Patent application number | Description | Published |
20080246136 | Chips having rear contacts connected by through vias to front contacts - A microelectronic unit is provided in which front and rear surfaces of a semiconductor element may define a thin region which has a first thickness and a thicker region having a thickness at least about twice the first thickness. A semiconductor device may be present at the front surface, with a plurality of first conductive contacts at the front surface connected to the device. A plurality of conductive vias may extend from the rear surface through the thin region of the semiconductor element to the first conductive contacts. A plurality of second conductive contacts can be exposed at an exterior of the semiconductor element. A plurality of conductive traces may connect the second conductive contacts to the conductive vias. | 10-09-2008 |
20080296709 | Chip assembly - The present invention provides an integrated circuit chip assembly and a method of manufacturing the same. The assembly includes a package element having a top surface and an integrated circuit chip having a top surface, a bottom surface, edge surface between the top and bottom surfaces, and contacts exposed at the top surface. The package element is disposed below the chip with the top surface of the package element facing toward the bottom surface of the chip. At least one spacer element resides between the top surface of the package element and the bottom surface of the chip. According to one embodiment, the at least one spacer element may form a substantially closed cavity between the package element and the integrated circuit chip. According to another embodiment, first conductive features may extend from the contacts of the chip along the top surface, and at least some of said first conductive features extend along at least one of the edge surfaces of the chip. | 12-04-2008 |
20080296717 | Packages and assemblies including lidded chips - A lidded chip is provided which includes a chip having a major surface and a plurality of first chip contacts exposed at the major surface. A lid overlies the major surface. A chip carrier is disposed between the chip and the lid, the chip carrier having an inner surface confronting the major surface and an outer surface confronting the lid. A plurality of first carrier contacts of the chip carrier are conductively connected to the first chip contacts. A plurality of second carrier contacts extend upwardly at least partially through the openings in the lid. | 12-04-2008 |
20080296748 | Transmission line stacking - A microelectronic unit has a structure including a microelectronic element such as a semiconductor chip with a first contact disposed remote from the periphery of the structure. The unit further includes first and second redistribution conductive pads disposed near a periphery of the structure and a conductive path incorporating first and second conductors extending toward the first contact, these conductors being connected to one another adjacent the first contact. The conductive path is connected to the first contact, and can provide signal routing from the periphery of the unit to the contact without the need for long stubs. A package may include a plurality of such units, which may be stacked on one another with the redistribution conductive pads of the various units connected to one another. | 12-04-2008 |
20080303132 | Semiconductor chip packages having cavities - Packaged microelectronic elements are provided which include a dielectric element, a cavity, a plurality of chip contacts and a plurality of package contacts, and microelectronic elements having a plurality of bond pads connected to the chip contacts. | 12-11-2008 |
20080315977 | Low loss RF transmission lines - A transmission structure having high propagation velocity and a low effective dielectric loss. The structure comprises a dielectric, a first reference conductor disposed below the dielectric, a signal conductor disposed above the dielectric, and a second reference conductor disposed over the signal conductor. The second reference conductor has a recess portion facing the signal conductor, the recess portion defining a gap between the second reference conductor and the signal conductor. The gap may be filled with air which has a relative dielectric constant approximately equal to one (1). Because of the physical and dielectric constant characteristics of the gap, the structure concentrates an electric field in the gap resulting in an effective dielectric constant approximately (approaching) one (1) and an effective dielectric loss approximately equal to zero (0). Thus, the structure exhibits a propagation velocity approximately equal to the speed of light. | 12-25-2008 |
20090002964 | Multilayer wiring element having pin interface - A method of forming contacts for an interconnection element, includes (a) joining a conductive element to an interconnection element having multiple wiring layers, (b) patterning the conductive element to form conductive pins, and (c) electrically interconnecting the conductive pins with conductive features of the interconnection element. A multiple wiring layer interconnection element having an exposed pin interface, includes an interconnection element having multiple wiring layers separated by at least one dielectric layer, the wiring layers including a plurality of conductive features exposed at a first face of the interconnection element, a plurality of conductive pins protruding in a direction away from the first face, and metal features electrically interconnecting the conductive features with the conductive pins. | 01-01-2009 |
20090014861 | Microelectronic package element and method of fabricating thereof - Microelectronic package elements and packages having dielectric layers and methods of fabricating such elements packages are disclosed. The elements and packages may advantageously be used in microelectronic assemblies having high routing density. | 01-15-2009 |
20090039528 | Wafer level stacked packages with individual chip selection - A method is provided for fabricating a stacked microelectronic assembly by steps including stacking and joining first and second like microelectronic substrates, each including a plurality of like microelectronic elements attached together at dicing lanes. Each microelectronic element has boundaries defined by edges including a first edge and a second edge. The first and second microelectronic substrates can be joined in different orientations, such that first edges of microelectronic elements of the first microelectronic substrate are aligned with second edges of microelectronic elements of the second microelectronic substrate. After exposing traces at the first and second edges of the microelectronic elements of the stacked microelectronic substrates, first and second leads can be formed which are connected to the exposed traces of the first and second microelectronic substrates, respectively. The second leads can be electrically isolated from the first leads. | 02-12-2009 |
20090045524 | Microelectronic package - A microelectronic package includes a lower unit having a lower unit substrate with conductive features and a top and bottom surface. The lower unit includes one or more lower unit chips overly/ing the top surface of the lower unit substrate that are electrically connected to the conductive features of the lower unit substrate. The microelectronic package also includes an upper unit including an upper unit substrate having conductive features, top and bottom surfaces and a hole extending between such top and bottom surfaces. The upper unit further includes one or more upper unit chips overlying the top surface of the upper unit substrate and electrically connected to the conductive features of the upper unit substrate by connections extending within the hole. The upper unit may include an upper unit encapsulant that covers the connections of the upper unit and the one or more upper unit chips. | 02-19-2009 |
20090065907 | Semiconductor packaging process using through silicon vias - A microelectronic unit | 03-12-2009 |
20090071000 | Formation of circuitry with modification of feature height - A connection component for mounting a chip or other microelectronic element is formed from a starting unit including posts projecting from a dielectric element by crushing or otherwise reducing the height of at least some of the posts. | 03-19-2009 |
20090071707 | Multilayer substrate with interconnection vias and method of manufacturing the same - A method is provided for manufacturing a multilayer substrate. An insulating layer can have a hole overlying a patterned second metal layer. In turn, the second metal layer can overlie a first metal layer. A third metal layer can be electroplated onto the patterned second metal layer within the hole, the third metal layer extending from the second metal layer onto a wall of the hole. When plating the third metal layer, the first and second metal layers can function as a conductive commoning element. | 03-19-2009 |
20090104736 | Stacked Packaging Improvements - A plurality of microelectronic assemblies ( | 04-23-2009 |
20090115047 | Robust multi-layer wiring elements and assemblies with embedded microelectronic elements - An interconnect element | 05-07-2009 |
20090133254 | Components with posts and pads - A packaged microelectronic element includes connection component incorporating a dielectric layer ( | 05-28-2009 |
20090160065 | Reconstituted Wafer Level Stacking - A stacked microelectronic assembly is fabricated from a structure which includes a plurality of first microelectronic elements having front faces bonded to a carrier. Each first microelectronic element may have a first edge and a plurality of first traces extending along the front face towards the first edge. After exposing at least a portion of the first traces, a dielectric layer is formed over the plurality of first microelectronic elements. After thinning the dielectric layer, a plurality of second microelectronic elements are aligned and joined with the structure such that front faces of the second microelectronic elements are facing the rear faces of the plurality of first microelectronic elements. Processing is repeated to form the desirable number of layers of microelectronic elements. In one embodiment, the stacked layers of microelectronic elements may be notched at dicing lines to expose edges of traces, which may then be electrically connected to leads formed in the notches. Individual stacked microelectronic units may be separated from the stacked microelectronic assembly by any suitable dicing, sawing or breaking technique. | 06-25-2009 |
20090162975 | Method of forming a wafer level package - A method is provided for forming a microelectronic package at a wafer level. Such method can include providing a semiconductor wafer having a surface with a pattern of electrical contacts thereon. An interposer component can be provided which has a compliant dielectric layer bonded to a conductive layer. A pattern of holes can be formed through the compliant dielectric layer and the conductive layer which corresponds to the pattern of electrical contacts. The compliant dielectric layer can be contacted with the semiconductor wafer surface so that the pattern of holes is in an aligned position with the pattern of contacts and the compliant dielectric layer and the semiconductor wafer surface then bonded in the aligned position to unite the semiconductor wafer and the interposer component to form a wafer level semiconductor package. The wafer level semiconductor package can be diced to form individual semiconductor chip packages. | 06-25-2009 |
20090212381 | WAFER LEVEL PACKAGES FOR REAR-FACE ILLUMINATED SOLID STATE IMAGE SENSORS - A solid state image sensor includes a microelectronic element having a front face and a rear face remote from the front face, the rear face having a recess extending towards the front surface. A plurality of light sensing elements may be disposed adjacent to the front face so as to receive light through the part of the rear face within the recess. A solid state image sensor can include a microelectronic element having a front face and a rear face remote from the front face, a plurality of light sensing elements disposed adjacent to the front face, the light sensing elements being arranged to receive light through the rear face. Electrically conductive package contacts may directly overlie the light sensing elements and the front face and be connected to chip contacts at the front face through openings in an insulating packaging layer overlying the front face. | 08-27-2009 |
20090316378 | Wafer level edge stacking - A microelectronic assembly can include a first microelectronic device and a second microelectronic device. Each microelectronic device has a die structure including at least one semiconductor die and each of the microelectronic devices has a first surface, a second surface remote from the first surface and at least one edge surface extending at angles other than a right angle away from the first and second surfaces. At least one electrically conductive element extends along the first surface onto at least one of the edge surfaces and onto the second surface. At least one conductive element of the first microelectronic device can be conductively bonded to the at least one conductive element of the second microelectronic device to provide an electrically conductive path therebetween. | 12-24-2009 |
20100009554 | Microelectronic interconnect element with decreased conductor spacing - A microelectronic interconnect element can include a plurality of first metal lines and a plurality of second metal lines interleaved with the first metal lines. Each of the first and second metal lines has a surface extending within the same reference plane. The first metal lines have surfaces above the reference plane and remote therefrom and the second metal lines have surfaces below the reference plane and remote therefrom. A dielectric layer can separate a metal line of the first metal lines from an adjacent metal line of the second metal lines. | 01-14-2010 |
20100044860 | Microelectronic substrate or element having conductive pads and metal posts joined thereto using bond layer - An interconnection element can include a substrate, e.g., a connection substrate, element of a package, circuit panel or microelectronic substrate, e.g., semiconductor chip, the substrate having a plurality of metal conductive elements such as conductive pads, contacts, bond pads, traces, or the like exposed at the surface. A plurality of solid metal posts may overlie and project away from respective ones of the conductive elements. An intermetallic layer can be disposed between the posts and the conductive elements, such layer providing electrically conductive interconnection between the posts and the conductive elements. Bases of the posts adjacent to the intermetallic layer can be aligned with the intermetallic layer. | 02-25-2010 |
20100053407 | Wafer level compliant packages for rear-face illuminated solid state image sensors - A solid state image sensor includes a microelectronic element having a front face and a rear face remote from the front face, the rear face having a recess extending towards the front surface. A plurality of light sensing elements may be disposed adjacent to the front face so as to receive light through the part of the rear face within the recess. A solid state image sensor can include a microelectronic element, e.g., a semiconductor chip, having a front face and a rear face remote from the front face, a plurality of light sensing elements disposed adjacent to the front face, the light sensing elements being arranged to receive light through the rear face. A packaging structure, which can include a compliant layer, can be attached to a front surface of the microelectronic element. Electrically conductive package contacts may directly overlie the light sensing elements and the front face and be connected to chip contacts at the front face through openings in an insulating packaging layer overlying the front face. | 03-04-2010 |
20100193970 | MICRO PIN GRID ARRAY WITH PIN MOTION ISOLATION - A microelectronic package includes a microelectronic element having faces and contacts, a flexible substrate overlying and spaced from a first face of the microelectronic element, and a plurality of conductive terminals exposed at a surface of the flexible substrate. The conductive terminals are electrically interconnected with the microelectronic element and the flexible substrate includes a gap extending at least partially around at least one of the conductive terminals. In certain embodiments, the package includes a support layer, such as a compliant layer, disposed between the first face of the microelectronic element and the flexible substrate. In other embodiments, the support layer includes at least one opening that is at least partially aligned with one of the conductive terminals. | 08-05-2010 |
20100197081 | MICROELECTRONIC PACKAGE WITH THERMAL ACCESS - A method of forming a microelectronic package including the steps of providing a three-layer metal plate, having a first layer, a second layer and a third layer. A plurality of conductive elements is formed from the first layer of the metal plate. A dielectric sheet is attached to the first layer of the metal plate, such that the dielectric sheet is remote from the third layer. A plurality of conductive features is then formed from the third layer of the metal plate which are also remote from the dielectric sheet. A microelectronic element is next electrically conducted to the conductive elements and a heat spreader is thermally connected the microelectronic element. | 08-05-2010 |
20100225006 | CHIPS HAVING REAR CONTACTS CONNECTED BY THROUGH VIAS TO FRONT CONTACTS - A microelectronic unit is provided in which front and rear surfaces of a semiconductor element may define a thin region which has a first thickness and a thicker region having a thickness at least about twice the first thickness. A semiconductor device may be present at the front surface, with a plurality of first conductive contacts at the front surface connected to the device. A plurality of conductive vias may extend from the rear surface through the thin region of the semiconductor element to the first conductive contacts. A plurality of second conductive contacts can be exposed at an exterior of the semiconductor element. A plurality of conductive traces may connect the second conductive contacts to the conductive vias. | 09-09-2010 |
20100230795 | STACKED MICROELECTRONIC ASSEMBLIES HAVING VIAS EXTENDING THROUGH BOND PADS - A stacked microelectronic assembly is provided which includes first and second stacked microelectronic elements. Each of the first and second microelectronic elements can include a conductive layer extending along a face of such microelectronic element. At least one of the first and second microelectronic elements can include a recess extending from the rear surface towards the front surface, and a conductive via extending from the recess through the bond pad and electrically connected to the bond pad, with a conductive layer connected to the via and extending along a rear face of the microelectronic element towards an edge of the microelectronic element. A plurality of leads can extend from the conductive layers of the first and second microelectronic elements and a plurality of terminals of the assembly can be electrically connected with the leads. | 09-16-2010 |
20100230812 | Microelectronic Assemblies Having Compliancy and Methods Therefor - A microelectronic assembly is disclosed that includes a semiconductor wafer with contacts, compliant bumps of dielectric material overlying the first surface of the semiconductor wafer, and a dielectric layer overlying the first surface of the semiconductor wafer and edges of the compliant bumps. The compliant bumps have planar top surfaces which are accessible through the dielectric layer. Conductive traces may be electrically connected with contacts and extend therefrom to overlie the planar top surfaces of the compliant bumps. Conductive elements may overlie the planar top surfaces in contact with the conductive traces. | 09-16-2010 |
20100230828 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND CONDUCTIVE REFERENCE ELEMENT - A microelectronic assembly can include a microelectronic device having device contacts exposed at a surface thereof and an interconnection element having element contacts and having a face adjacent to the microelectronic device. Conductive elements, e.g., wirebonds connect the device contacts with the element contacts and have portions extending in runs above the surface of the microelectronic device. A conductive layer has a conductive surface disposed at at least a substantially uniform distance above or below the plurality of the runs of the conductive elements. In some cases, the conductive material can have first and second dimensions in first and second horizontal directions which are smaller than first and second corresponding dimensions of the microelectronic device. The conductive material is connectable to a source of reference potential so as to achieve a desired impedance for the conductive elements. | 09-16-2010 |
20100232128 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND REFERENCE WIREBOND - A microelectronic assembly can include a microelectronic device, e.g., semiconductor chip, connected together with an interconnection element, e.g., substrate, the latter having signal contacts and reference contacts. The reference contacts can be connectable to a source of reference potential such as ground or a voltage source other than ground such as a voltage source used for power. Signal conductors, e.g., signal wirebonds can be connected to device contacts exposed at a surface of the microelectronic device. Reference conductors, e.g., reference wirebonds can be provided, at least one of which can be connected with two reference contacts of the interconnection element. The reference wirebond can have a run which extends at an at least substantially uniform spacing from a signal conductor, e.g., signal wirebond that is connected to the microelectronic device over at least a substantial portion of the length of the signal conductor. In such manner a desired impedance may be achieved for the signal conductor. | 09-16-2010 |
20100232129 | MICROELECTRONIC PACKAGES AND METHODS THEREFOR - A method of making a microelectronic assembly includes providing a microelectronic package having a substrate, a microelectronic element overlying the substrate and at least two conductive elements projecting from a surface of the substrate, the at least two conductive elements having surfaces remote from the surface of the substrate. The method includes compressing the at least two conductive elements so that the remote surfaces thereof lie in a common plane, and after the compressing step, providing an encapsulant material around the at least two conductive elements for supporting the microelectronic package and so that the remote surfaces of the at least two conductive elements remain accessible at an exterior surface of the encapsulant material. | 09-16-2010 |
20100258956 | MICROELECTRONIC PACKAGES AND METHODS THEREFOR - A microelectronic package includes a microelectronic element having faces and contacts, the microelectronic element having an outer perimeter, and a substrate overlying and spaced from a first face of the microelectronic element, whereby an outer region of the substrate extends beyond the outer perimeter of the microelectronic element. The microelectronic package includes a plurality of etched conductive posts exposed at a surface of the substrate and being electrically interconnected with the microelectronic element, whereby at least one of the etched conductive posts is disposed in the outer region of the substrate. The package includes an encapsulating mold material in contact with the microelectronic element and overlying the outer region of the substrate, the encapsulating mold material extending outside of the etched conductive posts for defining an outermost edge of the microelectronic package. | 10-14-2010 |
20100270679 | MICROELECTRONIC PACKAGES FABRICATED AT THE WAFER LEVEL AND METHODS THEREFOR - A method of making microelectronic packages includes making a subassembly by providing a plate having a top surface, a bottom surface and openings extending between the top and bottom surfaces, attaching a compliant layer to the top surface of the plate, the compliant layer having openings that are aligned with the openings extending through the plate, and providing electrically conductive features on the compliant layer. After making the subassembly, the bottom surface of the plate is attached with the top surface of a semiconductor wafer so that the openings extending through the plate are aligned with contacts on the wafer. At least some of the electrically conductive features on the compliant layer are electrically interconnected with the contacts on the semiconductor wafer. | 10-28-2010 |
20100273293 | SUBSTRATE FOR A MICROELECTRONIC PACKAGE AND METHOD OF FABRICATING THEREOF - Substrates having molded dielectric layers and methods of fabricating such substrates are disclosed. The substrates may advantageously be used in microelectronic assemblies having high routing density. | 10-28-2010 |
20110006432 | RECONSTITUTED WAFER STACK PACKAGING WITH AFTER-APPLIED PAD EXTENSIONS - A stacked microelectronic unit is provided which can include a plurality of vertically stacked microelectronic elements ( | 01-13-2011 |
20110012259 | PACKAGED SEMICONDUCTOR CHIPS - A chip-sized wafer level packaged device including a portion of a semiconductor wafer including a device, a packaging layer formed over the portion of the semiconductor wafer, the packaging layer including a material having thermal expansion characteristics similar to those of the semiconductor wafer and a ball grid array formed over a surface of the packaging layer and being electrically connected to the device. | 01-20-2011 |
20110031629 | EDGE CONNECT WAFER LEVEL STACKING - In accordance with an aspect of the invention, a stacked microelectronic package is provided which may include a plurality of subassemblies, e.g., a first subassembly and a second subassembly underlying the first subassembly. A front face of the second subassembly may confront the rear face of the first subassembly. Each of the first and second subassemblies may include a plurality of front contacts exposed at the front face, at least one edge and a plurality of front traces extending about the respective at least one edge. The second subassembly may have a plurality of rear contacts exposed at the rear face. The second subassembly may also have a plurality of rear traces extending from the rear contacts about the at least one edge. The rear traces may extend to at least some of the plurality of front contacts of at least one of the first or second subassemblies. | 02-10-2011 |
20110033979 | EDGE CONNECT WAFER LEVEL STACKING - A method of making a stacked microelectronic package by forming a microelectronic assembly by stacking a first subassembly including a plurality of microelectronic elements onto a second subassembly including a plurality of microelectronic elements, at least some of the plurality of microelectronic elements of said first subassembly and said second subassembly having traces that extend to respective edges of the microelectronic elements, then forming notches in the microelectronic assembly so as to expose the traces of at least some of the plurality of microelectronic elements, then forming leads at the side walls of the notches, the leads being in electrical communication with at least some of the traces and dicing the assembly into packages. Additional embodiments include methods for creating stacked packages using substrates and having additional traces that extend to both the top and bottom of the package. | 02-10-2011 |
20110042810 | STACKED PACKAGING IMPROVEMENTS - A plurality of microelectronic assemblies are made by severing an in-process unit including an upper substrate and lower substrate with microelectronic elements disposed between the substrates. In a further embodiment, a lead frame is joined to a substrate so that the leads project from this substrate. Lead frame is joined to a further substrate with one or more microelectronic elements disposed between the substrates. | 02-24-2011 |
20110049696 | OFF-CHIP VIAS IN STACKED CHIPS - A microelectronic assembly includes first and second stacked microelectronic elements, each having spaced apart traces extending along a front face and beyond at least a first edge thereof. An insulating region can contact the edges of each microelectronic element and at least portions of the traces of each microelectronic element extending beyond the respective first edges. The insulating region can define first and second side surfaces adjacent the first and second edges of the microelectronic elements. A plurality of spaced apart openings can extend along a side surface of the microelectronic assembly. Electrical conductors connected with respective traces can have portions disposed in respective openings and extending along the respective openings. The electrical conductors may extend to pads or solder balls overlying a face of one of the microelectronic elements. | 03-03-2011 |
20110095408 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND CONDUCTIVE REFERENCE ELEMENT - A microelectronic assembly can include a microelectronic device having device contacts exposed at a surface thereof and an interconnection element having element contacts and having a face adjacent to the microelectronic device. Conductive elements, e.g., wirebonds connect the device contacts with the element contacts and have portions extending in runs above the surface of the microelectronic device. A conductive layer has a conductive surface disposed at least a substantially uniform distance above or below the plurality of the runs of the conductive elements. In some cases, the conductive material can have first and second dimensions in first and second horizontal directions which are smaller than first and second corresponding dimensions of the microelectronic device. The conductive material is connectable to a source of reference potential so as to achieve a desired impedance for the conductive elements. | 04-28-2011 |
20110101535 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND CONDUCTIVE REFERENCE ELEMENT - A microelectronic assembly can include a microelectronic device having device contacts exposed at a surface thereof and an interconnection element having element contacts and having a face adjacent to the microelectronic device. Conductive elements, e.g., wirebonds connect the device contacts with the element contacts and have portions extending in runs above the surface of the microelectronic device. A conductive layer has a conductive surface disposed at least a substantially uniform distance above or below the plurality of the runs of the conductive elements. In some cases, the conductive material can have first and second dimensions in first and second horizontal directions which are smaller than first and second corresponding dimensions of the microelectronic device. The conductive material is connectable to a source of reference potential so as to achieve a desired impedance for the conductive elements. | 05-05-2011 |
20110147928 | MICROELECTRONIC ASSEMBLY WITH BOND ELEMENTS HAVING LOWERED INDUCTANCE - Microelectronic assemblies can have multiple conductive bond elements, e.g., bond wires, or a lead bond and a bond wire, extending between a pair of a substrate contact and a chip contact. E.g., a first bond wire can have ends joined to the contacts of the chip and substrate. A second bond wire can be joined to the ends of the first bond wire so that the second bond wire does not touch either the chip contact or the substrate contact to which the first bond wire is joined. In one example, a bond wire has a looped connection with first and second ends joined at a first contact and a middle portion joined to a second contact. In one example, first and second bond elements, e.g., bond wires or lead bonds can connect first and second pairs of a substrate contact with a chip contact. A third bond element, e.g., a bond wire or bond ribbon, can be joined to ends of the first and second bond elements. | 06-23-2011 |
20110147953 | MICROELECTRONIC ASSEMBLY WITH JOINED BOND ELEMENTS HAVING LOWERED INDUCTANCE - A microelectronic assembly includes a semiconductor chip having chip contacts exposed at a first face and a substrate juxtaposed with a face of the chip. A conductive bond element can electrically connect a first chip contact with a first substrate contact of the substrate, and a second conductive bond element can electrically connect the first chip contact with a second substrate contact. The first bond element can have a first end metallurgically joined to the first chip contact and a second end metallurgically joined to the first substrate contact. A first end of the second bond element can be metallurgically joined to the first bond element. The second bond element may or may not touch the first chip contact or the substrate contact. A third bond element can be joined to ends of first and second bond elements which are joined to substrate contacts or to chip contacts. In one embodiment, a bond element can have a looped connection, having first and second ends joined at a first contact and a middle portion joined to a second contact. | 06-23-2011 |
20110165733 | MICROELECTRONIC PACKAGES AND METHODS THEREFOR - A method of making a microelectronic assembly can include molding a dielectric material around at least two conductive elements which project above a height of a substrate having a microelectronic element mounted thereon, so that remote surfaces of the conductive elements remain accessible and exposed within openings extending from an exterior surface of the molded dielectric material. The remote surfaces can be disposed at heights from said surface of said substrate which are lower or higher than a height of the exterior surface of the molded dielectric material from the substrate surface. The conductive elements can be arranged to simultaneously carry first and second different electric potentials: e.g., power, ground or signal potentials. | 07-07-2011 |
20110187007 | EDGE CONNECT WAFER LEVEL STACKING - A stacked microelectronic assembly includes a first stacked subassembly and a second stacked subassembly overlying a portion of the first stacked subassembly. Each stacked subassembly includes at least a respective first microelectronic element having a face and a respective second microelectronic element having a face overlying and parallel to a face of the first microelectronic element. Each of the first and second microelectronic elements has edges extending away from the respective face. A plurality of traces at the respective face extend about at least one respective edge. Each of the first and second stacked subassemblies includes contacts connected to at least some of the plurality of traces. Bond wires conductively connect the contacts of the first stacked subassembly with the contacts of the second stacked subassembly. | 08-04-2011 |
20110230013 | STACKED PACKAGES WITH BRIDGING TRACES - A microelectronic assembly that includes a first microelectronic element having a first rear surface. The assembly further includes a second microelectronic element having a second rear surface. The second microelectronic element is attached to the first microelectronic element so as to form a stacked package. A bridging element electrically connects the first microelectronic element and the second microelectronic element. The first rear surface of the first microelectronic element faces toward the second rear surface of the second microelectronic element. | 09-22-2011 |
20110260320 | METHOD OF MAKING A CONNECTION COMPONENT WITH POSTS AND PADS - A packaged microelectronic element includes connection component incorporating a dielectric layer ( | 10-27-2011 |
20110266668 | MICROELECTRONIC ASSEMBLIES HAVING COMPLIANCY - A microelectronic assembly includes a microelectronic element, such as a semiconductor wafer or semiconductor chip, having a first surface and contacts accessible at the first surface, and a compliant layer overlying the first surface of the microelectronic element, the compliant layer having openings in substantial alignment with the contacts of the microelectronic element. The assembly desirably includes conductive posts overlying the compliant layer and projecting away from the first surface of the microelectronic element, the conductive posts being electrically interconnected with the contacts of the microelectronic element by elongated, electrically conductive elements extending between the contacts and the conductive posts. | 11-03-2011 |
20110269272 | MICROELECTRONIC PACKAGES AND METHODS THEREFOR - A microelectronic package includes a microelectronic element having faces and contacts, the microelectronic element having an outer perimeter, and a substrate overlying and spaced from a first face of the microelectronic element, whereby an outer region of the substrate extends beyond the outer perimeter of the microelectronic element. The microelectronic package includes a plurality of etched conductive posts exposed at a surface of the substrate and being electrically interconnected with the microelectronic element, whereby at least one of the etched conductive posts is disposed in the outer region of the substrate. The package includes an encapsulating mold material in contact with the microelectronic element and overlying the outer region of the substrate, the encapsulating mold material extending outside of the etched conductive posts for defining an outermost edge of the microelectronic package. | 11-03-2011 |
20110285020 | MICROELECTRONIC ASSEMBLY WITH JOINED BOND ELEMENTS HAVING LOWERED INDUCTANCE - A microelectronic assembly includes a semiconductor chip having chip contacts exposed at a first face and a substrate juxtaposed with a face of the chip. A conductive bond element can electrically connect a first chip contact with a first substrate contact of the substrate, and a second conductive bond element can electrically connect the first chip contact with a second substrate contact. The first bond element can have a first end metallurgically joined to the first chip contact and a second end metallurgically joined to the first substrate contact. A first end of the second bond element can be metallurgically joined to the first bond element. The second bond element may or may not touch the first chip contact or the substrate contact. A third bond element can be joined to ends of first and second bond elements which are joined to substrate contacts or to chip contacts. In one embodiment, a bond element can have a looped connection, having first and second ends joined at a first contact and a middle portion joined to a second contact. | 11-24-2011 |
20110291297 | MICROELECTRONIC PACKAGES HAVING CAVITIES FOR RECEIVING MICROELECTRONIC ELEMENTS - Packaged microelectronic elements are provided which include a dielectric element, a cavity, a plurality of chip contacts and a plurality of package contacts, and microelectronic elements having a plurality of bond pads connected to the chip contacts. | 12-01-2011 |
20120007232 | MICROELECTRONIC PACKAGES WITH DUAL OR MULTIPLE-ETCHED FLIP-CHIP CONNECTORS - A packaged microelectronic element includes a microelectronic element having a front surface and a plurality of first solid metal posts extending away from the front surface. A substrate has a major surface and a plurality of conductive elements exposed at the major surface and joined to the first solid metal posts. In particular examples, the conductive elements can be bond pads or can be second posts having top surfaces and edge surfaces extending at substantial angles away therefrom. Each first solid metal post includes a base region adjacent the microelectronic element and a tip region remote from the microelectronic element, the base region and tip region having respective concave circumferential surfaces. Each first solid metal post has a horizontal dimension which is a first function of vertical location in the base region and which is a second function of vertical location in the tip region. | 01-12-2012 |
20120013000 | STACKABLE MOLDED MICROELECTRONIC PACKAGES - A microelectronic package has a microelectronic element overlying or mounted to a first surface of a substrate and substantially rigid conductive posts projecting above the first surface or projecting above a second surface of the substrate remote therefrom. Conductive elements exposed at a surface of the substrate opposite the surface above which the conductive posts project are electrically interconnected with the microelectronic element. An encapsulant overlies at least a portion of the microelectronic element and the surface of the substrate above which the conductive posts project, the encapsulant having a recess or a plurality of openings each permitting at least one electrical connection to be made to at least one conductive post. At least some conductive posts are electrically insulated from one another and adapted to simultaneously carry different electric potentials. In particular embodiments, the openings in the encapsulant at least partially expose conductive masses joined to posts, fully expose top surfaces of posts and partially expose edge surfaces of posts, or may only partially expose top surfaces of posts. | 01-19-2012 |
20120013001 | STACKABLE MOLDED MICROELECTRONIC PACKAGES WITH AREA ARRAY UNIT CONNECTORS - A microelectronic package having a substrate, a microelectronic element, e.g., a chip, and terminals can have conductive elements electrically connected with element contacts of the chip and contacts of the substrate. Conductive elements can be electrically insulated from one another for simultaneously carrying different electric potentials. An encapsulant can overlie the first surface of the substrate and at least a portion of a face of the microelectronic element remote from the substrate, and may have a major surface above the microelectronic element. A plurality of package contacts can overlie a face of the microelectronic element remote from the substrate. The package contacts, e.g., conductive masses, substantially rigid posts, can be electrically interconnected with terminals of the substrate, such as through the conductive elements. The package contacts can have top surfaces at least partially exposed at the major surface of the encapsulant. | 01-19-2012 |
20120013028 | STACKED MICROELECTRONIC PACKAGES HAVING AT LEAST TWO STACKED MICROELECTRONIC ELEMENTS ADJACENT ONE ANOTHER - A microelectronic assembly includes first and second microelectronic elements. Each of the microelectronic elements has oppositely-facing first and second surfaces and edges bounding the surfaces. The first microelectronic element is disposed on the second microelectronic element with the second surface of the first microelectronic element facing toward the first surface of the second microelectronic element. The first microelectronic element preferably extends beyond at least one edge of the second microelectronic element and the second microelectronic element preferably extends beyond at least one edge of the first microelectronic element. A first edge of the first microelectronic element has a length that is smaller than a first edge of the second microelectronic element. A second edge of the first microelectronic element has a length that is greater than the second edge of the second microelectronic element. | 01-19-2012 |
20120018863 | MICROELECTRONIC ELEMENTS WITH REAR CONTACTS CONNECTED WITH VIA FIRST OR VIA MIDDLE STRUCTURES - A microelectronic unit includes a microelectronic element, e.g., an integrated circuit chip, having a semiconductor region of monocrystalline form. The semiconductor region has a front surface extending in a first direction, an active circuit element adjacent the front surface, a rear surface remote from the front surface, and a conductive via which extends towards the rear surface. The conductive via can be insulated from the semiconductor region by an inorganic dielectric layer. An opening can extend from the rear surface partially through a thickness of the semiconductor region, with the opening and the conductive via having respective widths in the first direction. The width of the opening may be greater than the width of the conductive via where the opening meets the conductive via. A rear contact can be electrically connected to the conductive via and exposed at the rear surface for electrical connection with an external circuit element, such as another like microelectronic unit, a microelectronic package, or a circuit panel. | 01-26-2012 |
20120018868 | MICROELECTRONIC ELEMENTS HAVING METALLIC PADS OVERLYING VIAS - A microelectronic unit, an interconnection substrate, and a method of fabricating a microelectronic unit are disclosed. A microelectronic unit can include a semiconductor element having a plurality of active semiconductor devices therein, the semiconductor element having a first opening extending from a rear surface partially through the semiconductor element towards a front surface and at least one second opening, and a dielectric region overlying a surface of the semiconductor element in the first opening. The microelectronic unit can include at least one conductive interconnect electrically connected to a respective conductive via and extending away therefrom within the aperture. In a particular embodiment, at least one conductive interconnect can extend within the first opening and at least one second opening, the conductive interconnect being electrically connected with a conductive pad having a top surface exposed at the front surface of the semiconductor element. | 01-26-2012 |
20120018893 | METHODS OF FORMING SEMICONDUCTOR ELEMENTS USING MICRO-ABRASIVE PARTICLE STREAM - A method of fabricating a microelectronic unit includes providing a semiconductor element having a front surface and a rear surface remote from the front surface, forming at least one first opening extending from the rear surface partially through the semiconductor element towards the front surface by directing a jet of fine abrasive particles towards the semiconductor element, and forming at least one conductive contact and at least one conductive interconnect coupled thereto. The semiconductor element can include a plurality of active semiconductor devices therein. The semiconductor element can include a plurality of conductive pads exposed at the front surface. Each conductive interconnect can extend within one or more of the first openings and can be coupled directly or indirectly to at least one of the conductive pads. Each of the conductive contacts can be exposed at the rear surface of the semiconductor element for electrical connection to an external device. | 01-26-2012 |
20120018894 | NON-LITHOGRAPHIC FORMATION OF THREE-DIMENSIONAL CONDUCTIVE ELEMENTS - A method of forming a conductive element on a substrate and the resulting assembly are provided. The method includes forming a groove in a sacrificial layer overlying a dielectric region disposed on a substrate. The groove preferably extends along a sloped surface of the substrate. The sacrificial layer is preferably removed by a non-photolithographic method, such as ablating with a laser, mechanical milling, or sandblasting. A conductive element is formed in the groove. The grooves may be formed. The grooves and conductive elements may be formed along any surface of the substrate, including within trenches and vias formed therein, and may connect to conductive pads on the front and/or rear surface of the substrate. The conductive elements are preferably formed by plating and may or may not conform to the surface of the substrate. | 01-26-2012 |
20120018895 | ACTIVE CHIP ON CARRIER OR LAMINATED CHIP HAVING MICROELECTRONIC ELEMENT EMBEDDED THEREIN - A structure including a first semiconductor chip with front and rear surfaces and a cavity in the rear surface. A second semiconductor chip is mounted within the cavity. The first chip may have vias extending from the cavity to the front surface and via conductors within these vias serving to connect the additional microelectronic element to the active elements of the first chip. The structure may have a volume comparable to that of the first chip alone and yet provide the functionality of a multi-chip assembly. A composite chip incorporating a body and a layer of semiconductor material mounted on a front surface of the body similarly may have a cavity extending into the body from the rear surface and may have an additional microelectronic element mounted in such cavity. | 01-26-2012 |
20120020026 | MICROELECTRONIC ELEMENTS WITH POST-ASSEMBLY PLANARIZATION - A microelectronic unit includes a carrier structure having a front surface, a rear surface remote from the front surface, and a recess having an opening at the front surface and an inner surface located below the front surface of the carrier structure. The microelectronic unit can include a microelectronic element having a bottom surface adjacent the inner surface, a top surface remote from the bottom surface, and a plurality of contacts at the top surface. The microelectronic element can include terminals electrically connected with the contacts of the microelectronic element. The microelectronic unit can include a dielectric region contacting at least the top surface of the microelectronic element. The dielectric region can have a planar surface located coplanar with or above the front surface of the carrier structure. The terminals can be exposed at the surface of the dielectric region for interconnection with an external element. | 01-26-2012 |
20120025365 | MICROELECTRONIC PACKAGES WITH NANOPARTICLE JOINING - A method of making an assembly includes the steps of applying metallic nanoparticles to exposed surfaces of conductive elements of either of or both of a first component and a second component, juxtaposing the conductive elements of the first component with the conductive elements of the second component with the metallic nanoparticles disposed therebetween, and elevating a temperature at least at interfaces of the juxtaposed conductive elements to a joining temperature at which the metallic nanoparticles cause metallurgical joints to form between the juxtaposed conductive elements. The conductive elements of either of or both of the first component and the second component can include substantially rigid posts having top surfaces projecting a height above the surface of the respective component and edge surfaces extending at substantial angles away from the top surfaces thereof. | 02-02-2012 |
20120032349 | METHOD OF FABRICATING STACKED ASSEMBLY INCLUDING PLURALITY OF STACKED MICROELECTRONIC ELEMENTS - A method is provided for fabricating a stacked microelectronic assembly by steps including stacking and joining first and second like microelectronic substrates, each including a plurality of like microelectronic elements attached together at dicing lanes. Each microelectronic element has boundaries defined by edges including a first edge and a second edge. The first and second microelectronic substrates can be joined in different orientations, such that first edges of microelectronic elements of the first microelectronic substrate are aligned with second edges of microelectronic elements of the second microelectronic substrate. After exposing traces at the first and second edges of the microelectronic elements of the stacked microelectronic substrates, first and second leads can be formed which are connected to the exposed traces of the first and second microelectronic substrates, respectively. The second leads can be electrically isolated from the first leads. | 02-09-2012 |
20120056324 | SUBSTRATE FOR A MICROELECTRONIC PACKAGE AND METHOD OF FABRICATING THEREOF - Substrates having molded dielectric layers and methods of fabricating such substrates are disclosed. The substrates may advantageously be used in microelectronic assemblies having high routing density. | 03-08-2012 |
20120068317 | TSOP WITH IMPEDANCE CONTROL - A semiconductor device of an illustrative embodiment includes a die, a lead frame including a plurality of leads having substantial portions arranged in a lead plane and electrically connected to the die. Most preferably, the package includes at least a substantial portion of one conductive element arranged in a plane positioned adjacent the lead frame and substantially parallel to the lead plane, the conductive element being capacitively coupled to the leads such that the conductive element and at least one of the leads cooperatively define a controlled-impedance conduction path, and an encapsulant which encapsulates the leads and the conductive element. The leads and, desirably, the conductive element have respective connection regions which are not covered by the encapsulant. | 03-22-2012 |
20120068327 | MULTI-FUNCTION AND SHIELDED 3D INTERCONNECTS - A microelectronic unit includes a semiconductor element consisting essentially of semiconductor material and having a front surface, a rear surface, a plurality of active semiconductor devices adjacent the front surface, a plurality of conductive pads exposed at the front surface, and an opening extending through the semiconductor element. At least one of the conductive pads can at least partially overlie the opening and can be electrically connected with at least one of the active semiconductor devices. The microelectronic unit can also include a first conductive element exposed at the rear surface for connection with an external component, the first conductive element extending through the opening and electrically connected with the at least one conductive pad, and a second conductive element extending through the opening and insulated from the first conductive element. The at least one conductive pad can overlie a peripheral edge of the second conductive element. | 03-22-2012 |
20120068330 | STAGED VIA FORMATION FROM BOTH SIDES OF CHIP - A method of fabricating a semiconductor assembly can include providing a semiconductor element having a front surface, a rear surface, and a plurality of conductive pads, forming at least one hole extending at least through a respective one of the conductive pads by processing applied to the respective conductive pad from above the front surface, forming an opening extending from the rear surface at least partially through a thickness of the semiconductor element, such that the at least one hole and the opening meet at a location between the front and rear surfaces, and forming at least one conductive element exposed at the rear surface for electrical connection to an external device, the at least one conductive element extending within the at least one hole and at least into the opening, the conductive element being electrically connected with the respective conductive pad. | 03-22-2012 |
20120068338 | IMPEDANCE CONTROLLED PACKAGES WITH METAL SHEET OR 2-LAYER RDL - A microelectronic assembly is disclosed that is capable of achieving a desired impedance for raised conductive elements. The microelectronic assembly may include an interconnection element, a surface conductive element, a microelectronic device, a plurality of raised conductive elements, and a bond element. The microelectronic device may overlie the dielectric element and at least one surface conductive element attached to the front surface. The plurality of raised conductive elements may connect the device contacts with the element contacts. The raised conductive elements may have substantial portions spaced a first height above and extending at least generally parallel to at least one surface conductive element, such that a desired impedance may be achieved for the raised conductive elements. A bond element may electrically connect at least one surface conductive element with at least one reference contact that may be connectable to a source of reference potential. | 03-22-2012 |
20120068351 | CHIP ASSEMBLY HAVING VIA INTERCONNECTS JOINED BY PLATING - An assembly and method of making same are provided. The assembly can be formed by juxtaposing a first electrically conductive element overlying a major surface of a first semiconductor element with an electrically conductive pad exposed at a front surface of a second semiconductor element. An opening can be formed extending through the conductive pad of the second semiconductor element and exposing a surface of the first conductive element. The opening may alternatively be formed extending through the first conductive element. A second electrically conductive element can be formed extending at least within the opening and electrically contacting the conductive pad and the first conductive element. A third semiconductor element can be positioned in a similar manner with respect to the second semiconductor element. | 03-22-2012 |
20120068352 | STACKED CHIP ASSEMBLY HAVING VERTICAL VIAS - An assembly and method of making same are provided. The assembly can be formed by stacking a first semiconductor element atop a second semiconductor element and forming an electrically conductive element extending through openings of the semiconductor elements. The openings may be staged. The conductive element can conform to contours of the interior surfaces of the openings and can electrically connect conductive pads of the semiconductor elements. A dielectric region can be provided at least substantially filling the openings of the semiconductor elements, and the electrically conductive element can extend through an opening formed in the dielectric region. | 03-22-2012 |
20120068361 | STACKED MULTI-DIE PACKAGES WITH IMPEDANCE CONTROL - A microelectronic assembly may include microelectronic devices arranged in a stack and having device contacts exposed at respective front surfaces. Signal conductors having substantial portions extending above the front surface of the respective microelectronic devices connect the device contacts with signal contacts of an underlying interconnection element. A rear surface of a microelectronic device of the stack overlying an adjacent microelectronic device of the stack is spaced a predetermined distance above and extends at least generally parallel to the substantial portions of the signal conductors connected to the adjacent device, such that a desired impedance may be achieved for the signal conductors connected to the adjacent device. | 03-22-2012 |
20120068365 | METAL CAN IMPEDANCE CONTROL STRUCTURE - A microelectronic assembly includes an interconnection element, element contacts, first and second metal layers, conductive elements, and first and second microelectronic devices. The first metal layer may extend beyond at least one of the edges of the first microelectronic device. The conductive elements may respectively extend beyond at least one of the edges of the first metal layer. The first metal layer may have a surface disposed at a substantially uniform spacing from at least substantial portions of the conductive elements, such that a desired impedance may be achieved for the conductive elements. The conductive elements may be spaced a smaller distance from the metal layer than the distance of the conductive elements from the front surface of the first microelectronic device. The second metal layer may be connectable to a source of reference potential. | 03-22-2012 |
20120080807 | OFF-CHIP VIAS IN STACKED CHIPS - A microelectronic assembly includes first and second stacked microelectronic elements, each having spaced apart traces extending along a front face and beyond at least a first edge thereof. An insulating region can contact the edges of each microelectronic element and at least portions of the traces of each microelectronic element extending beyond the respective first edges. The insulating region can define first and second side surfaces adjacent the first and second edges of the microelectronic elements. A plurality of spaced apart openings can extend along a side surface of the microelectronic assembly. Electrical conductors connected with respective traces can have portions disposed in respective openings and extending along the respective openings. The electrical conductors may extend to pads or solder balls overlying a face of one of the microelectronic elements. | 04-05-2012 |
20120091582 | MICROELECTRONIC ASSEMBLIES HAVING COMPLIANCY AND METHODS THEREFOR - A microelectronic assembly is disclosed that includes a semiconductor wafer with contacts, compliant bumps of dielectric material overlying the first surface of the semiconductor wafer, and a dielectric layer overlying the first surface of the semiconductor wafer and edges of the compliant bumps. The compliant bumps have planar top surfaces which are accessible through the dielectric layer. Conductive traces may be electrically connected with contacts and extend therefrom to overlie the planar top surfaces of the compliant bumps. Conductive elements may overlie the planar top surfaces in contact with the conductive traces. | 04-19-2012 |
20120092832 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND IMPROVED THERMAL CHARACTERISTICS - A microelectronic assembly includes a dielectric element having oppositely-facing first and second surfaces and one or more apertures extending between the surfaces, the dielectric element further having conductive elements thereon; a first microelectronic element having a rear surface and a front surface facing the first surface of the dielectric element, the first microelectronic element having a first edge and a plurality of contacts exposed at the front surface thereof; a second microelectronic element including having a rear surface and a front surface facing the rear surface of the first microelectronic element, a projecting portion of the front surface of the second microelectronic element extending beyond the first edge of the first microelectronic element, the projecting portion being spaced from the first surface of the dielectric element, the second microelectronic element having a plurality of contacts exposed at the projecting portion of the front surface; leads extending from contacts of the microelectronic elements through the at least one aperture to at least some of the conductive elements; and a heat spreader thermally coupled to at least one of the first microelectronic element or the second microelectronic element. | 04-19-2012 |
20120104595 | NO FLOW UNDERFILL - A method for making a microelectronic assembly includes providing a microelectronic element with first conductive elements and a dielectric element with second conductive elements. At least some of either the first conductive elements or the second conductive elements may be conductive posts and other of the first or second conductive elements may include a bond metal disposed between some of the conductive posts. An underfill layer may overly some of the first or second conductive elements. At least one of the first conductive elements may be moved towards the other of the second conductive elements so that the posts pierce the underfill layer and at least deform the bond metal. The microelectronic element and the dielectric element can be heated to join them together. The height of the posts above the surface may be at least forty percent of a distance between surfaces of the microelectronic element and dielectric element. | 05-03-2012 |
20120119367 | CONDUCTIVE PADS DEFINED BY EMBEDDED TRACES - An assembly and method of making same are provided. The assembly can include a first component including a dielectric region having an exposed surface, a conductive pad at the surface defined by a conductive element having at least a portion extending in an oscillating or spiral path along the surface, and a an electrically conductive bonding material joined to the conductive pad and bridging an exposed portion of the dielectric surface between adjacent segments. The conductive pad can permit electrical interconnection of the first component with a second component having a terminal joined to the pad through the electrically conductive bonding material. The path of the conductive element may or may not overlap or cross itself. | 05-17-2012 |
20120119380 | MICROELECTRONIC PACKAGE WITH TERMINALS ON DIELECTRIC MASS - A package for a microelectronic element, such as a semiconductor chip, has a dielectric mass overlying the package substrate and microelectronic element and has top terminals exposed at the top surface of the dielectric mass. Traces extending along edge surfaces of the dielectric mass desirably connect the top terminals to bottom terminals on the package substrate. The dielectric mass can be formed, for example, by molding or by application of a conformal layer. | 05-17-2012 |
20120126389 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND VIAS CONNECTED TO THE CENTRAL CONTACTS - The microelectronic assembly includes a first microelectronic element having a front surface, a plurality of contacts exposed at the front surface, and a rear surface remote from the front surface; a second microelectronic element having a front surface facing the rear surface of the first microelectronic element and projecting beyond an edge of the first microelectronic element, the second microelectronic element having a plurality of contacts exposed at its front surface; a dielectric region overlying the front surfaces of the microelectronic elements, the dielectric region having a major surface facing away from the microelectronic elements; metallized vias within openings in the dielectric region extending from the plurality of contacts of the first and second microelectronic elements; and leads extending along a major surface of the dielectric region from the vias to terminals exposed at the major surface. | 05-24-2012 |
20120126407 | WAFER LEVEL CHIP PACKAGE AND A METHOD OF FABRICATING THEREOF - Wafer level chip packages including risers having sloped sidewalls and methods of fabricating such chip packages are disclosed. The inventive wafer level chip packages may advantageously be used in various microelectronic assemblies. | 05-24-2012 |
20120139082 | STACKED MICROELECTRONIC ASSEMBY WITH TSVS FORMED IN STAGES AND CARRIER ABOVE CHIP - A microelectronic assembly is provided which includes a first element consisting essentially of at least one of semiconductor or inorganic dielectric material having a surface facing and attached to a major surface of a microelectronic element at which a plurality of conductive pads are exposed, the microelectronic element having active semiconductor devices therein. A first opening extends from an exposed surface of the first element towards the surface attached to the microelectronic element, and a second opening extends from the first opening to a first one of the conductive pads, wherein where the first and second openings meet, interior surfaces of the first and second openings extend at different angles relative to the major surface of the microelectronic element. A conductive element extends within the first and second openings and contacts the at least one conductive pad. | 06-07-2012 |
20120139094 | STACKED MICROELECTRONIC ASSEMBLY HAVING INTERPOSER CONNECTING ACTIVE CHIPS - A microelectronic assembly can include first and second microelectronic elements each embodying active semiconductor devices adjacent a front surface thereof, and having an electrically conductive pad exposed at the respective front surface. An interposer of material having a CTE less than 10 ppm/° C. has first and second surfaces attached to the front surfaces of the respective first and second microelectronic elements, the interposer having a second conductive element extending within an opening in the interposer. First and second conductive elements extend within openings extending from the rear surface of a respective microelectronic element of the first and second microelectronic elements towards the front surface of the respective microelectronic element. In one example, one or more of the first or second conductive elements extends through the respective first or second pad, and the conductive elements contact the exposed portions of the second conductive element to provide electrical connection therewith. | 06-07-2012 |
20120139124 | STACKED MICROELECTRONIC ASSEMBLY WITH TSVS FORMED IN STAGES WITH PLURAL ACTIVE CHIPS - A microelectronic assembly is provided in which first and second electrically conductive pads exposed at front surfaces of first and second microelectronic elements, respectively, are juxtaposed, each of the microelectronic elements embodying active semiconductor devices. An electrically conductive element may extend within a first opening extending from a rear surface of the first microelectronic element towards the front surface thereof, within a second opening extending from the first opening towards the front surface of the first microelectronic element, and within a third opening extending through at least one of the first and second pads to contact the first and second pads. Interior surfaces of the first and second openings may extend in first and second directions relative to the front surface of the first microelectronic element, respectively, to define a substantial angle. | 06-07-2012 |
20120146182 | HIGH DENSITY THREE-DIMENSIONAL INTEGRATED CAPACITORS - A component includes a substrate and a capacitor formed in contact with the substrate. The substrate can consist essentially of a material having a coefficient of thermal expansion of less than 10 ppm/° C. The substrate can have a surface and an opening extending downwardly therefrom. The capacitor can include at least first and second pairs of electrically conductive plates and first and second electrodes. The first and second pairs of plates can be connectable with respective first and second electric potentials. The first and second pairs of plates can extend along an inner surface of the opening, each of the plates being separated from at least one adjacent plate by a dielectric layer. The first and second electrodes can be exposed at the surface of the substrate and can be coupled to the respective first and second pairs of plates. | 06-14-2012 |
20120146206 | PIN ATTACHMENT - A microelectronic package includes a substrate having a first region, a second region, a first surface, and a second surface remote from the first surface. At least one microelectronic element overlies the first region on the first surface. First electrically conductive elements are exposed at one of the first surface and the second surface of the substrate within the second region with at least some of the first conductive elements electrically connected to the at least one microelectronic element. Substantially rigid metal elements overlie the first conductive elements and have end surfaces remote therefrom. A bond metal joins the metal elements with the first conductive elements, and a molded dielectric layer overlies at least the second region of the substrate and has a surface remote from the substrate. The end surfaces of the metal elements are at least partially exposed at the surface of the molded dielectric layer. | 06-14-2012 |
20120146210 | COMPLIANT INTERCONNECTS IN WAFERS - A microelectronic assembly includes a substrate and an electrically conductive element. The substrate can have a CTE less than 10 ppm/° C., a major surface having a recess not extending through the substrate, and a material having a modulus of elasticity less than 10 GPa disposed within the recess. The electrically conductive element can include a joining portion overlying the recess and extending from an anchor portion supported by the substrate. The joining portion can be at least partially exposed at the major surface for connection to a component external to the microelectronic unit. | 06-14-2012 |
20120152433 | DUAL WAFER SPIN COATING - A method of bonding a first substrate and a second substrate includes the steps of rotating first substrate with an adhesive mass thereon, and second substrate contacting the mass and overlying the first substrate, controlling a vertical height of a heated control platen spaced apart from and not contacting the second substrate so as to control a temperature of the adhesive mass, so as to at least one of bond the first and second substrates in alignment with one another, or achieve a sufficiently planar adhesive interface between the first and second substrates. | 06-21-2012 |
20120153426 | VOID-FREE WAFER BONDING USING CHANNELS - A method of bonding first and second microelectronic elements includes pressing together a first substrate containing active circuit elements therein with a second substrate, with a flowable dielectric material between confronting surfaces of the respective substrates, each of the first and second substrates having a coefficient of thermal expansion less than 10 parts per million/° C., at least one of the confronting surfaces having a plurality of channels extending from an edge of such surface, such that the dielectric material between planes defined by the confronting surfaces is at least substantially free of voids and has a thickness over one micron, and at least some of the dielectric material flows into at least some of the channels. | 06-21-2012 |
20120153435 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND IMPROVED GROUND OR POWER DISTRIBUTION - A microelectronic assembly includes a dielectric element having at least one aperture and electrically conductive elements thereon including terminals exposed at the second surface of the dielectric element; a first microelectronic element having a rear surface and a front surface facing the dielectric element, the first microelectronic element having a plurality of contacts exposed at the front surface thereof; a second microelectronic element having a rear surface and a front surface facing the rear surface of the first microelectronic element, the second microelectronic element having a plurality of contacts exposed at the front surface and projecting beyond an edge of the first microelectronic element; and an electrically conductive plane attached to the dielectric element and at least partially positioned between the first and second apertures, the electrically conductive plane being electrically connected with one or more of the contacts of at least one of the first or second microelectronic elements. | 06-21-2012 |
20120153488 | SIMULTANEOUS WAFER BONDING AND INTERCONNECT JOINING - Disclosed are a microelectronic assembly of two elements and a method of forming same. A microelectronic element includes a major surface, and a dielectric layer and at least one bond pad exposed at the major surface. The microelectronic element may contain a plurality of active circuit elements. A first metal layer is deposited overlying the at least one bond pad and the dielectric layer. A second element having a second metal layer deposited thereon is provided, and the first metal layer is joined with the second metal layer. The assembly may be severed along dicing lanes into individual units each including a chip. | 06-21-2012 |
20120155042 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND IMPROVED GROUND OR POWER DISTRIBUTION - A microelectronic assembly includes a dielectric element, first and second microelectronic elements, signal leads, and one or more jumper leads. The dielectric element has oppositely-facing first and second surfaces and first and second apertures extend between the surfaces. A plurality of electrically conductive elements are positioned thereon. Signal leads are connected to one or more of the microelectronic elements and extend through one or more of the first or second apertures to some of the conductive elements on the dielectric element. One or more jumper leads extend through the first aperture and are connected to a contact of the first microelectronic element. The one or more jumper leads span over the second aperture and are connected to a conductive element on the dielectric element. | 06-21-2012 |
20120155049 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS - A microelectronic assembly includes a dielectric element having first and second surfaces, first and second apertures extending between the first and second surfaces and defining a central region of the first surface between the first and second apertures, first and second microelectronic elements, and leads extending from contacts exposed at respective front surfaces of the first and second microelectronic elements to central terminals exposed at the central region. The front surface of the first microelectronic element can face the second surface of the dielectric element. The front surface of the second microelectronic element can face a rear surface of the first microelectronic element. The contacts of the second microelectronic element can project beyond an edge of the first microelectronic element. At least first and second ones of the leads can electrically interconnect a first central terminal of the central terminals with each of the first and second microelectronic elements. | 06-21-2012 |
20120155055 | SEMICONDUCTOR CHIP ASSEMBLY AND METHOD FOR MAKING SAME - A microelectronic assembly may include a substrate including a rigid dielectric layer having electrically conductive elements, a microelectronic element having a plurality of contacts exposed at a face thereof, and conductive vias extending through a compliant dielectric layer overlying the rigid dielectric layer. The vias electrically connect the substrate contacts respectively to the conductive elements, and the substrate contacts are joined respectively to the contacts of the microelectronic element. The vias, compliant layer and substrate contacts are adapted to appreciably relieve stress at the substrate contacts associated with differential thermal contact and expansion of the assembly. | 06-21-2012 |
20120181658 | HIGH DENSITY THREE-DIMENSIONAL INTEGRATED CAPACITORS - A capacitor can include a substrate having a first surface, a second surface remote from the first surface, and a through opening extending between the first and second surfaces, first and second metal elements, and a capacitor dielectric layer separating and insulating the first and second metal elements from one another at least within the through opening. The first metal element can be exposed at the first surface and can extend into the through opening. The second metal element can be exposed at the second surface and can extend into the through opening. The first and second metal elements can be electrically connectable to first and second electric potentials. The capacitor dielectric layer can have an undulating shape. | 07-19-2012 |
20120199924 | BSI IMAGE SENSOR PACKAGE WITH VARIABLE LIGHT TRANSMISSION FOR EVEN RECEPTION OF DIFFERENT WAVELENGTHS - A microelectronic image sensor assembly for backside illumination and method of making same are provided. The assembly includes a microelectronic element having contacts exposed at a front face and light sensing elements arranged to receive light of different wavelengths through a semiconductor region adjacent a rear face. The semiconductor region has a first region of material overlying the first light sensing element and a second region of material overlying the second light sensing element such that the first and second wavelengths are able to pass through the first and second regions, respectively, and reach the first and second light sensing elements with substantially the same intensity. | 08-09-2012 |
20120199925 | BSI IMAGE SENSOR PACKAGE WITH EMBEDDED ABSORBER FOR EVEN RECEPTION OF DIFFERENT WAVELENGTHS - A microelectronic image sensor assembly for backside illumination and method of making same are provided. The assembly includes a microelectronic element having contacts exposed at a front face and light sensing elements arranged to receive light of different wavelengths through a rear face. A semiconductor region has an opening overlying at least one of first and second light sensing elements, the semiconductor region having a first thickness between the first light sensing element and the rear face and a second thickness between the second light sensing element and the rear face. A light-absorbing material overlies the semiconductor region within the opening above at least one of the light sensing elements such that the first and second light sensing elements receive light of substantially the same intensity. | 08-09-2012 |
20120199926 | BSI IMAGE SENSOR PACKAGE WITH VARIABLE-HEIGHT SILICON FOR EVEN RECEPTION OF DIFFERENT WAVELENGTHS - A microelectronic image sensor assembly for backside illumination and method of making same are provided. The assembly includes a microelectronic element having contacts exposed at a front face and light sensing elements arranged to receive light of different wavelengths through a rear face. A semiconductor region has a first thickness between the first light sensing element and the rear face and a second thickness between the second light sensing element and the rear face such that the first and second light sensing elements receive light of substantially the same intensity. A dielectric region is provided at least substantially filling a space of the semiconductor region adjacent at least one of the light sensing elements. The dielectric region may include at least one light guide. | 08-09-2012 |
20120241960 | SUBSTRATE FOR A MICROELECTRONIC PACKAGE AND METHOD OF FABRICATING THEREOF - Substrates having molded dielectric layers and methods of fabricating such substrates are disclosed. The substrates may advantageously be used in microelectronic assemblies having high routing density. | 09-27-2012 |
20120241976 | SEMICONDUCTOR PACKAGING PROCESS USING THROUGH SILICON VIAS - A microelectronic unit can include a semiconductor element having a front surface, a microelectronic semiconductor device adjacent to the front surface, contacts at the front surface and a rear surface remote from the front surface. The semiconductor element can have through holes extending from the rear surface through the semiconductor element and through the contacts. A dielectric layer can line the through holes. A conductive layer may overlie the dielectric layer within the through holes. The conductive layer can conductively interconnect the contacts with unit contacts. | 09-27-2012 |
20120267751 | INTERPOSER HAVING MOLDED LOW CTE DIELECTRIC - A method for making an interconnection component is disclosed, including forming a plurality of metal posts extending away from a reference surface. Each post is formed having a pair of opposed end surface and an edge surface extending therebetween. A dielectric layer is formed contacting the edge surfaces and filling spaces between adjacent ones of the posts. The dielectric layer has first and second opposed surfaces adjacent the first and second end surfaces. The dielectric layer has a coefficient of thermal expansion of less than 8 ppm/° C. The interconnection component is completed such that it has no interconnects between the first and second end surfaces of the posts that extend in a lateral direction. First and second pluralities of wettable contacts are adjacent the first and second opposed surfaces. The wettable contacts are usable to bond the interconnection component to a microelectronic element or a circuit panel. | 10-25-2012 |
20120267771 | STACKED CHIP-ON-BOARD MODULE WITH EDGE CONNECTOR - A module can include a module card and first and second microelectronic elements having front surfaces facing a first surface of the module card. The module card can also have a second surface and a plurality of parallel exposed edge contacts adjacent an edge of at least one of the first and second surfaces for mating with corresponding contacts of a socket when the module is inserted in the socket. Each microelectronic element can be electrically connected to the module card. The front surface of the second microelectronic element can partially overlie a rear surface of the first microelectronic element and can be attached thereto. | 10-25-2012 |
20120267777 | MULTI-CHIP MODULE WITH STACKED FACE-DOWN CONNECTED DIES - A microelectronic assembly can include a substrate having first and second surfaces, at least two logic chips overlying the first surface, and a memory chip having a front surface with contacts thereon, the front surface of the memory chip confronting a rear surface of each logic chip. The substrate can have conductive structure thereon and terminals exposed at the second surface for connection with a component. Signal contacts of each logic chip can be directly electrically connected to signal contacts of the other logic chips through the conductive structure of the substrate for transfer of signals between the logic chips. The logic chips can be adapted to simultaneously execute a set of instructions of a given thread of a process. The contacts of the memory chip can be directly electrically connected to the signal contacts of at least one of the logic chips through the conductive structure of the substrate. | 10-25-2012 |
20120267789 | VIAS IN POROUS SUBSTRATES - A microelectronic unit can include a substrate having front and rear surfaces and active semiconductor devices therein, the substrate having a plurality of openings arranged in a symmetric or asymmetric distribution across an area of the rear surface, first and second conductive vias connected to first and second pads exposed at the front surface, pluralities of first and second conductive interconnects extending within respective ones of the openings, and first and second conductive contacts exposed for interconnection with an external element. The plurality of first conductive interconnects can be separated from the plurality of second conductive interconnects by at least one of the plurality of openings, the at least one opening at least partially filled with an insulating material. The distribution of the openings can include at least m openings spaced apart in a first direction and n openings spaced apart in a second direction transverse to the first direction. | 10-25-2012 |
20120267796 | FLIP-CHIP, FACE-UP AND FACE-DOWN CENTERBOND MEMORY WIREBOND ASSEMBLIES - A microelectronic assembly can include a substrate having first and second surfaces and an aperture extending therebetween, the substrate having terminals. The assembly can also include a first microelectronic element having a front surface facing the first surface of the substrate, a second microelectronic element having a front surface facing the first microelectronic element and projecting beyond an edge of the first microelectronic element, first and second leads electrically connecting contacts of the respective first and second microelectronic elements to the terminals, and third leads electrically interconnecting the contacts of the first and second microelectronic elements. The contacts of the first microelectronic element can be exposed at the front surface thereof adjacent the edge thereof. The contacts of the second microelectronic element can be disposed in a central region of the front surface thereof. The first, second, and third leads can have portions aligned with the aperture. | 10-25-2012 |
20120267797 | FLIP-CHIP, FACE-UP AND FACE-DOWN WIREBOND COMBINATION PACKAGE - A microelectronic assembly can include a substrate having an aperture extending between first and second surfaces thereof, the substrate having substrate contacts at the first surface and terminals at the second surface. The microelectronic assembly can include a first microelectronic element having a front surface facing the first surface, a second microelectronic element having a front surface facing the first microelectronic element, and leads electrically connecting the contacts of the second microelectronic element with the terminals. The second microelectronic element can have contacts exposed at the front surface thereof beyond an edge of the first microelectronic element. The first microelectronic element can be configured to regenerate at least some signals received by the microelectronic assembly at the terminals and to transmit said signals to the second microelectronic element. The second microelectronic element can embody a greater number of active devices to provide memory storage array function than any other function. | 10-25-2012 |
20120267798 | MULTIPLE DIE FACE-DOWN STACKING FOR TWO OR MORE DIE - A microelectronic assembly is disclosed that comprises a substrate having first and second openings, a first microelectronic element and a second microelectronic element in a face-down position. The first element has an active surface facing the front surface of the substrate and bond pads aligned with the first opening, a rear surface remote therefrom, and an edge extending between the front and rear surfaces. The second microelectronic element has a front surface facing the first microelectronic element and projecting beyond an edge of the first microelectronic element, and bond pads at the front surface of the second microelectronic element aligned with the second opening. | 10-25-2012 |
20120268899 | REINFORCED FAN-OUT WAFER-LEVEL PACKAGE - A microelectronic package includes a microelectronic element including a first surface having contacts thereon, a second surface remote therefrom, and edge surfaces extending between the first and second surfaces. A reinforcing layer adheres to the at least one edge surface and extends in a direction away therefrom, the reinforcing layer not extending along the first surface of the microelectronic element. A conductive redistribution layer including a plurality of conductive elements extends from the contacts along the first surface and along a surface of the reinforcing layer beyond the at least one edge surface. An encapsulant overlies at least the reinforcing layer. The microelectronic element has a first coefficient of thermal expansion, the encapsulant has a second coefficient of thermal expansion, and the reinforcing layer has a third coefficient of thermal expansion that is between the first and second coefficients of thermal expansion. | 10-25-2012 |
20120273933 | THREE-DIMENSIONAL SYSTEM-IN-A-PACKAGE - A microelectronic assembly can include first, second and third stacked substantially planar elements, e.g., of dielectric or semiconductor material, and which may have a CTE of less than 10 ppm/° C. The assembly may be a microelectronic package and may incorporate active semiconductor devices in one, two or more of the first, second or third elements to function cooperatively as a system-in-a-package. In one example, an electrically conductive element having a minimum thickness less than 10 microns, may be formed by plating, and may electrically connect two or more of the first, second or third elements. The conductive element may entirely underlie a surface of another one of the substantially planar elements. | 11-01-2012 |
20120286416 | SEMICONDUCTOR CHIP PACKAGE ASSEMBLY AND METHOD FOR MAKING SAME - A microelectronic assembly may include a microelectronic element having a plurality of element contacts at a face thereof, and a compliant dielectric element having a Young's modulus of less than about two gigapascal (GPa) and substrate contacts at a first surface joined to the element contacts. The substrate contacts may be electrically connected with terminals at a second surface of the compliant dielectric element that opposes the first surface, through conductive vias in the compliant dielectric element. A rigid underfill may be between the face of the microelectronic element and the first surface of the compliant dielectric element. The terminals may be usable for bonding the microelectronic assembly to corresponding contacts of a component external to the microelectronic assembly. | 11-15-2012 |
20120306092 | CONDUCTIVE PADS DEFINED BY EMBEDDED TRACES - An assembly and method of making same are provided. The assembly can include a first component including a dielectric region having an exposed surface, a conductive pad at the surface defined by a conductive element having at least a portion extending in an oscillating or spiral path along the surface, and a an electrically conductive bonding material joined to the conductive pad and bridging an exposed portion of the dielectric surface between adjacent segments. The conductive pad can permit electrical interconnection of the first component with a second component having a terminal joined to the pad through the electrically conductive bonding material. The path of the conductive element may or may not overlap or cross itself. | 12-06-2012 |
20120313228 | IMPEDENCE CONTROLLED PACKAGES WITH METAL SHEET OR 2-LAYER RDL - A microelectronic assembly includes an interconnection element, a conductive plane, a microelectronic device, a plurality of traces, and first and second bond elements. The interconnection element includes a dielectric element, a plurality of element contacts, and at least one reference contact thereon. The microelectronic device includes a front surface with device contacts exposed thereat. The conductive plane overlies a portion of the front surface of the microelectronic device. Traces overlying a surface of the conductive plane are insulated therefrom and electrically connected with the element contacts. The traces also have substantial portions spaced a first height above and extending at least generally parallel to the conductive plane, such that a desired impedance is achieved for the traces. First bond element electrically connects the at least one conductive plane with the at least one reference contact. Second bond elements electrically connect device contacts with the traces. | 12-13-2012 |
20120313238 | SEMICONDUCTOR CHIP PACKAGE ASSEMBLY AND METHOD FOR MAKING SAME - A microelectronic assembly may include a substrate containing a dielectric element having first and second opposed surfaces. The dielectric element may include a first dielectric layer adjacent the first surface, and a second dielectric layer disposed between the first dielectric layer and the second surface. A Young's modulus of the first dielectric layer may be at least 50% greater than the Young's modulus of the second dielectric layer, which is less than two gigapascal (GPa). A conductive structure may extend through the first and second dielectric layers and electrically connect substrate contacts at the first surface with terminals at the second surface. The substrate contacts may be joined with contacts of a microelectronic element through conductive masses, and a rigid underfill may be between the microelectronic element and the first surface. The terminals may be usable to bond the microelectronic assembly to contacts of a component external to the microelectronic assembly. | 12-13-2012 |
20120313242 | SUBSTRATE AND ASSEMBLY THEREOF WITH DIELECTRIC REMOVAL FOR INCREASED POST HEIGHT - An interconnection substrate includes a plurality of electrically conductive elements of at least one wiring layer defining first and second lateral directions. Electrically conductive projections for bonding to electrically conductive contacts of at least one component external to the substrate, extend from the conductive elements above the at least one wiring layer. The conductive projections have end portions remote from the conductive elements and neck portions between the conductive elements and the end portions. The end portions have lower surfaces extending outwardly from the neck portions in at least one of the lateral directions. The substrate further includes a dielectric layer overlying the conductive elements and extending upwardly along the neck portions at least to the lower surfaces. At least portions of the dielectric layer between the conductive projections are recessed below a height of the lower surfaces. | 12-13-2012 |
20120313253 | FAN-OUT WLP WITH PACKAGE - A microelectronic package includes a microelectronic unit and a substrate. The microelectronic unit includes a microelectronic element having contacts on a front face. A dielectric material has a first surface substantially flush with the front face of the microelectronic element. Conductive traces have at least portions extending along the front face away from the contacts, at least some of which also extend along the first surface of the dielectric material. Contacts are connected with the traces, at least some of which are disposed at the first surface of the dielectric material. The substrate has first and second opposed surfaces and an edge extending therebetween, the first surface facing the front face of the microelectronic unit, and the second surface having a plurality of terminals thereon configured for electrical connection with at least one external component. Masses of conductive matrix material join the terminals with the redistribution contacts. | 12-13-2012 |
20120313264 | CHIP WITH SINTERED CONNECTIONS TO PACKAGE - A microelectronic package and method of making same are provided. The package includes a substrate having first and second opposed surfaces, an edge surface extending therebetween, a plurality of terminals, and a plurality of conductive elements electrically connected with the terminals. The edge surface can be disposed at a periphery of the substrate or can be the edge surface of an aperture within the substrate. A microelectronic element has a front face and contacts thereon, with at least some of the contacts being adjacent to the edge surface of the substrate. A dielectric material overlies the edge surface of the substrate and defines a sloping surface between the front face of the microelectronic element and the substrate. A conductive matrix material defines a plurality of conductive interconnects extending along the sloping surface. The conductive interconnects electrically interconnect respective ones of the contacts with the conductive elements. | 12-13-2012 |
20120319282 | Reliable Packaging and Interconnect Structures - Methods and apparatus for forming a semiconductor device are provided which may include any number of features. One feature is a method of forming an interconnect structure that results in the interconnect structure having a top surface and portions of the side walls of the interconnect structure covered in a dissimilar material. In some embodiments, the dissimilar material can be a conductive material or a nano-alloy. The interconnect structure can be formed by removing a portion of the interconnect structure, and covering the interconnect structure with the dissimilar material. The interconnect structure can comprise a damascene structure, such as a single or dual damascene structure, or alternatively, can comprise a silicon-through via (TSV) structure. | 12-20-2012 |
20120326313 | SINGLE EXPOSURE IN MULTI-DAMASCENE PROCESS - Methods of fabricating a multi-layer semiconductor device such as a multi-layer damascene or inverted multi-layer damascene structure using only a single or reduced number of exposure steps. The method may include etching a precursor structure formed of materials with differential removal rates for a given removal condition. The method may include removing material from a multi-layer structure under different removal conditions. Further disclosed are multi-layer damascene structures having multiple cavities of different sizes. The cavities may have smooth inner wall surfaces. The layers of the structure may be in direct contact. The cavities may be filled with a conducting metal or an insulator. Multi-layer semiconductor devices using the methods and structures are further disclosed. | 12-27-2012 |
20130010441 | MICROELECTRONIC ELEMENTS WITH POST-ASSEMBLY PLANARIZATION - A microelectronic unit can include a carrier structure having a front surface, a rear surface remote from the front surface, and a recess having an opening at the front surface and an inner surface located below the front surface of the carrier structure. The microelectronic unit can also include a microelectronic element having a top surface adjacent the inner surface, a bottom surface remote from the top surface, and a plurality of contacts at the top surface. The microelectronic unit can also include terminals electrically connected with the contacts of the microelectronic element. The terminals can be electrically insulated from the carrier structure. The microelectronic unit can also include a dielectric region contacting at least the bottom surface of the microelectronic element. The dielectric region can define a planar surface located coplanar with or above the front surface of the carrier structure. | 01-10-2013 |
20130014978 | Electrical Barrier LayersAANM Uzoh; CyprianAACI San JoseAAST CAAACO USAAGP Uzoh; Cyprian San Jose CA USAANM Oganesian; VageAACI Palo AltoAAST CAAACO USAAGP Oganesian; Vage Palo Alto CA USAANM Mohammed; IlyasAACI Santa ClaraAAST CAAACO USAAGP Mohammed; Ilyas Santa Clara CA USAANM Haba; BelgacemAACI SaratogaAAST CAAACO USAAGP Haba; Belgacem Saratoga CA USAANM Savalia; PiyushAACI Santa ClaraAAST CAAACO USAAGP Savalia; Piyush Santa Clara CA USAANM Mitchell; CraigAACI San JoseAAST CAAACO USAAGP Mitchell; Craig San Jose CA US - Barrier layers for use in electrical applications. In some embodiments the barrier layer is a laminated barrier layer. In some embodiments the barrier layer includes a graded barrier layer. | 01-17-2013 |
20130015586 | DE-SKEWED MULTI-DIE PACKAGES - A microelectronic package may have a plurality of terminals disposed at a face thereof which are configured for connection to at least one external component. e.g., a circuit panel. First and second microelectronic elements can be affixed with packaging structure therein. A first electrical connection can extend from a respective terminal of the package to a corresponding contact on the first microelectronic element, and a second electrical connection can extend from the respective terminal to a corresponding contact on the second microelectronic element, the first and second connections being configured such that a respective signal carried by the first and second connections in each group is subject to propagation delay of the same duration between the respective terminal and each of the corresponding contacts coupled thereto. | 01-17-2013 |
20130015590 | MEMORY MODULE IN A PACKAGE - A microelectronic package can include a substrate having first and second opposed surfaces, at least two pairs of microelectronic elements, and a plurality of terminals exposed at the second surface. Each pair of microelectronic elements can include an upper microelectronic element and a lower microelectronic element. The pairs of microelectronic elements can be fully spaced apart from one another in a horizontal direction parallel to the first surface of the substrate. Each lower microelectronic element can have a front surface facing the first surface of the substrate and a plurality of contacts at the front surface. A surface of each of the upper microelectronic elements can at least partially overlie a rear surface of the lower microelectronic element in its pair. The microelectronic package can also include electrical connections extending from at least some of the contacts of each lower microelectronic element to at least some of the terminals. | 01-17-2013 |
20130015591 | MEMORY MODULE IN A PACKAGE - A microelectronic package can include a substrate having first and second opposed surfaces, first, second, third, and fourth microelectronic elements, and a plurality of terminals exposed at the second surface. Each microelectronic element can have a front surface facing the first surface of the substrate and a plurality of contacts at the front surface. The front surfaces of the microelectronic elements can be arranged in a single plane parallel to the first surface. Each microelectronic element can have a column of contacts exposed at the front surface and arranged along respective first, second, third, and fourth axes. The first and third axes can be parallel to one another. The second and fourth axes can be transverse to the first and third axes. The microelectronic package can also include electrical connections extending from at least some of the contacts of each microelectronic element to at least some of the terminals. | 01-17-2013 |
20130026645 | LOW STRESS VIAS - A component can include a substrate having a front surface and a rear surface remote therefrom, an opening extending from the rear surface towards the front surface, and a conductive via extending within the opening. The substrate can have a CTE less than 10 ppm/° C. The opening can define an inner surface between the front and rear surfaces. The conductive via can include a first metal layer overlying the inner surface and a second metal region overlying the first metal layer and electrically coupled to the first metal layer. The second metal region can have a CTE greater than a CTE of the first metal layer. The conductive via can have an effective CTE across a diameter of the conductive via that is less than 80% of the CTE of the second metal region. | 01-31-2013 |
20130032387 | MICROELECTRONIC PACKAGE WITH TERMINALS ON DIELECTRIC MASS - A package for a microelectronic element, such as a semiconductor chip, has a dielectric mass overlying the package substrate and microelectronic element and has top terminals exposed at the top surface of the dielectric mass. Traces extending along edge surfaces of the dielectric mass desirably connect the top terminals to bottom terminals on the package substrate. The dielectric mass can be formed, for example, by molding or by application of a conformal layer. | 02-07-2013 |
20130032944 | MICROELECTRONIC PACKAGE WITH STACKED MICROELECTRONIC ELEMENTS AND METHOD FOR MANUFACTURE THEREOF - A microelectronic package may include a stacked microelectronic unit including at least first and second vertically stacked microelectronic elements each having a front face facing a top surface of the package. The front face of the first element may be adjacent the top surface, and the first element may overlie the front face of the second element such that at least a portion of the front face of the second element having an element contact thereon extends beyond an edge of the first element. A conductive structure may electrically connect a first terminal at the top surface to an element contact at the front face of the second element, and include a continuous monolithic metal feature extending along the top surface and through at least a portion of an encapsulant, which is between the top surface and the front face of the second element, towards the element contact. | 02-07-2013 |
20130043582 | MULTIPLE DIE IN A FACE DOWN PACKAGE - A microelectronic package includes a subassembly including a first substrate and first and second microelectronic elements having contact-bearing faces facing towards oppositely-facing first and second surfaces of the first substrate and each having contacts electrically connected with the first substrate. The contact-bearing faces of the first and second microelectronic elements at least partially overlie one another. Leads electrically connect the subassembly with a second substrate, at least portions of the leads being aligned with an aperture in the second substrate. The leads can include wire bonds extending through an aperture in the first substrate and joined to contacts of the first microelectronic element aligned with the first substrate aperture. In one example, the subassembly can be electrically connected with the second substrate using electrically conductive spacer elements. | 02-21-2013 |
20130049196 | THROUGH INTERPOSER WIRE BOND USING LOW CTE INTERPOSER WITH COARSE SLOT APERTURES - A microelectronic package includes a subassembly, a second substrate, and a monolithic encapsulant. The subassembly includes a first substrate that has at least one aperture, a coefficient of thermal expansion (CTE) of eight parts per million per degree Celsius or less, and first and second contacts arranged so as to have a pitch of 200 microns or less. First and second microelectronic elements are respectively electrically connected to the first and second contacts. Wire bonds may be used to connect the second element contacts with the second contacts. A second substrate may underlie either the first or the second microelectronic elements and be electrically interconnected with the first substrate. The second substrate may have terminals configured for electrical connection to a component external to the microelectronic package. A monolithic encapsulant may contact the first and second microelectronic elements and the first and second substrates. | 02-28-2013 |
20130056870 | FLIP-CHIP, FACE-UP AND FACE-DOWN WIREBOND COMBINATION PACKAGE - A microelectronic assembly can include a substrate having oppositely-facing first and second surfaces and a first aperture extending between the first and second surfaces, a first microelectronic element having a surface facing the first surface, a second microelectronic element having a front surface facing the first microelectronic element, signal leads connected to contacts of the second microelectronic element and extending through the first aperture to at least some of a plurality of electrically conductive elements on the substrate, and at least one power regulation component having active circuit elements therein disposed between the first surface of the substrate and the front surface of the second microelectronic element. The first microelectronic element can have another surface remote from the surface of the first microelectronic element, and an edge extending between the surfaces thereof. The contacts of the second microelectronic element can project beyond the edge of the first microelectronic element. | 03-07-2013 |
20130063918 | LOW CTE INTERPOSER - An interconnection component includes a first support portion has a plurality of first conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent a first surface and a second end adjacent a second surface. A second support portion has a plurality of second conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent the first surface and a second end adjacent the second surface. A redistribution layer is disposed between the second surfaces of the first and second support portions, electrically connecting at least some of the first vias with at least some of the second vias. The first and second support portions can have a coefficient of thermal expansion (“CTE”) of less than 12 parts per million per degree, Celsius (“ppm/° C.”). | 03-14-2013 |
20130065390 | CHIPS HAVING REAR CONTACTS CONNECTED BY THROUGH VIAS TO FRONT CONTACTS - A method of fabricating a microelectronic unit can include providing a semiconductor element having front and rear surfaces, a plurality of conductive pads each having a top surface exposed at the front surface and a bottom surface remote from the top surface, and a first opening extending from the rear surface towards the front surface. The method can also include forming at least one second opening extending from the first opening towards the bottom surface of a respective one of the pads. The method can also include forming a conductive via, a conductive interconnect, and a contact, the conductive via in registration with and in contact with the conductive pad and extending within the second opening, the contact exposed at an exterior of the microelectronic unit, the conductive interconnect electrically connecting the conductive via with the contact and extending away from the via at least partly within the first opening. | 03-14-2013 |
20130082375 | STUB MINIMIZATION FOR ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A system or microelectronic assembly can include one or more microelectronic packages each having a substrate and a microelectronic element having a face and one or more columns of contacts thereon which face and are joined to corresponding contacts on a surface of the substrate. An axial plane may intersect the face along a line in the first direction and centered relative to the columns of element contacts. Columns of package terminals can extend in the first direction. First terminals in a central region of the second surface can be configured to carry address information usable to determine an addressable memory location within the microelectronic element. The central region may have a width not more than three and one-half times a minimum pitch between the columns of package terminals. The axial plane can intersect the central region. | 04-04-2013 |
20130082380 | STUB MINIMIZATION USING DUPLICATE SETS OF SIGNAL TERMINALS IN ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic package can include a microelectronic element having a face and a plurality of element contacts thereon, a substrate having first and second surfaces, and terminals on the second surface configured for connecting the package with an external component. The microelectronic element can include a plurality of stacked electrically interconnected semiconductor chips. The substrate can have contacts facing the element contacts of the microelectronic element and joined thereto. The terminals can include first terminals arranged at positions within first and second parallel grids. The first terminals of each grid can be configured to carry address information usable by circuitry within the microelectronic package to determine an addressable memory location from among all the available addressable memory locations within the microelectronic element. The signal assignments of the first terminals in the first grid can be a mirror image of the signal assignments of the first terminals in the second grid. | 04-04-2013 |
20130082381 | STUB MINIMIZATION USING DUPLICATE SETS OF TERMINALS FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic element having a memory storage array has a front face facing away from a substrate of a microelectronic package, and is electrically connected with the substrate through conductive structure extending above the front face. First terminals are disposed at locations within first and second parallel grids of the package. The first terminals of each grid are configured to carry address information usable to determine an addressable memory location from among all the available addressable memory locations of the memory storage array. The first terminals in the first grid have signal assignments which are a mirror image of the signal assignments of the first terminals in the second grid. | 04-04-2013 |
20130082389 | STUB MINIMIZATION FOR ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic package can include a substrate and a microelectronic element having a face and one or more columns of contacts thereon which face and are joined to corresponding contacts on a surface of the substrate. An axial plane may intersect the face along a line in the first direction and centered relative to the columns of element contacts. Columns of package terminals can extend in the first direction. First terminals in a central region of the second surface can be configured to carry address information usable to determine an addressable memory location within the microelectronic element. The central region may have a width not more than three and one-half times a minimum pitch between the columns of package terminals. The axial plane can intersect the central region. | 04-04-2013 |
20130082390 | STUB MINIMIZATION USING DUPLICATE SETS OF TERMINALS FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic assembly can include a microelectronic package connected with a circuit panel. The package has a microelectronic element having a front face facing away from a substrate of the package, and electrically connected with the substrate through conductive structure extending above the front face. First terminals provided in first and second parallel grids or in first and second individual columns can be configured to carry address information usable to determine an addressable memory location from among all the available addressable memory locations of the memory storage array. The first terminals in the first grid can have signal assignments which are a mirror image of the signal assignments of the first terminals in the second grid. | 04-04-2013 |
20130082391 | STUB MINIMIZATION FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic assembly can include a circuit panel having first and second surfaces and panel contacts at each surface, and first and second microelectronic packages having terminals mounted to the panel contacts at the first and second surfaces, respectively. The circuit panel can electrically interconnect terminals of the first package with corresponding terminals of the second package. Each package can include a substrate having first and second surfaces, a microelectronic element, conductive structure extending above a front face of the microelectronic element, and parallel columns of terminals at the second surface. The terminals of each package can include first terminals in a central region of the respective second surface and configured to carry address information usable by circuitry within the package to determine an addressable memory location within the respective microelectronic element. Each central region can have a width within three and one-half times a minimum pitch between adjacent terminals. | 04-04-2013 |
20130082394 | STUB MINIMIZATION FOR MULTI-DIE WIREBOND ASSEMBLIES WITH PARALLEL WINDOWS - A microelectronic package can include a substrate having first and second opposed surfaces and first and second apertures extending between the first and second surfaces, first and second microelectronic elements each having a surface facing the first surface of the substrate, a plurality of terminals exposed at the second surface in a central region thereof, and leads electrically connected between contacts of each microelectronic element and the terminals. The apertures can have first and second parallel axes extending in directions of the lengths of the respective apertures. The second surface can have a central region disposed between the first and second axes. Each microelectronic element can embody a greater number of active devices to provide memory storage array function than any other function. The terminals can be configured to carry all of the address signals transferred to the microelectronic package. | 04-04-2013 |
20130082395 | STUB MINIMIZATION USING DUPLICATE SETS OF SIGNAL TERMINALS IN ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic package can include a microelectronic element having a face and a plurality of element contacts thereon, a substrate having first and second surfaces, and terminals on the second surface configured for connecting the package with at least one external component. The substrate can have substrate contacts on the first surface facing the element contacts of the microelectronic element and joined thereto. The terminals can include first terminals arranged at positions within first and second parallel grids. The first terminals of each grid can be configured to carry address information usable by circuitry within the microelectronic package to determine an addressable memory location from among all the available addressable memory locations of a memory storage array within the microelectronic element. The signal assignments of the first terminals in the first grid can be a mirror image of the signal assignments of the first terminals in the second grid. | 04-04-2013 |
20130082396 | STUB MINIMIZATION USING DUPLICATE SETS OF TERMINALS FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic element having a memory storage array has a front face facing away from a substrate of a microelectronic package, and is electrically connected with the substrate through conductive structure extending above the front face. First terminals are disposed at locations within first and second parallel grids of the package. The first terminals of each grid are configured to carry address information usable to determine an addressable memory location from among all the available addressable memory locations of the memory storage array. The first terminals in the first grid have signal assignments which are a mirror image of the signal assignments of the first terminals in the second grid. | 04-04-2013 |
20130082397 | STUB MINIMIZATION FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic package can include a substrate and a microelectronic element having a rear face facing a first surface of the substrate, a front face, and a column of element contacts extending in a first direction. The microelectronic element can include stacked electrically interconnected semiconductor chips. Edges of the microelectronic element can define an axial plane extending in the first direction and a third direction normal to the rear face. The package can include columns of terminals extending in the first direction at a second surface of the substrate. The terminals can include first terminals exposed in a central region of the second surface and configured to carry address information usable by circuitry within the package to determine an addressable memory location. The central region may have a width not more than 3.5 times a minimum pitch between adjacent terminal columns. The axial plane can intersect the central region. | 04-04-2013 |
20130082398 | STUB MINIMIZATION FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic package can include a substrate and a microelectronic element having a rear face facing a first surface of the substrate, a front face, and a column of element contacts extending in a first direction. Edges of the microelectronic element can define an axial plane extending in the first direction and a third direction normal to the rear face. The package can include columns of terminals extending in the first direction at a second surface of the substrate. The terminals can include first terminals exposed in a central region of the second surface and configured to carry address information usable by circuitry within the package to determine an addressable memory location within the microelectronic element. The central region may have a width not more than three and one-half times a minimum pitch between any two adjacent columns of the terminals. The axial plane can intersect the central region. | 04-04-2013 |
20130083582 | STUB MINIMIZATION FOR ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic package can include a substrate and a microelectronic element having a face and one or more columns of contacts thereon which face and are joined to corresponding contacts on a surface of the substrate. An axial plane may intersect the face along a line in the first direction and centered relative to the columns of element contacts. Columns of package terminals can extend in the first direction. First terminals in a central region of the second surface can be configured to carry address information usable to determine an addressable memory location within the microelectronic element. The central region may have a width not more than three and one-half times a minimum pitch between the columns of package terminals. The axial plane can intersect the central region. | 04-04-2013 |
20130083583 | STUB MINIMIZATION FOR MULTI-DIE WIREBOND ASSEMBLIES WITH PARALLEL WINDOWS - A microelectronic package can include a substrate having first and second opposed surfaces and first and second apertures extending between the first and second surfaces, first and second microelectronic elements each having a surface facing the first surface of the substrate, a plurality of terminals exposed at the second surface in a central region thereof, and leads electrically connected between contacts of each microelectronic element and the terminals. The apertures can have first and second parallel axes extending in directions of the lengths of the respective apertures. The central region of the second surface can be disposed between the first and second axes. The terminals can be configured to carry address information usable by circuitry within the microelectronic package to determine an addressable memory location from among all the available addressable memory locations of a memory storage array within the microelectronic elements. | 04-04-2013 |
20130099376 | MICROELECTRONIC PACKAGES WITH DUAL OR MULTIPLE-ETCHED FLIP-CHIP CONNECTORS - A packaged microelectronic element includes a microelectronic element having a front surface and a plurality of first solid metal posts extending away from the front surface. A substrate has a major surface and a plurality of conductive elements exposed at the major surface and joined to the first solid metal posts. In particular examples, the conductive elements can be bond pads or can be second posts having top surfaces and edge surfaces extending at substantial angles away therefrom. Each first solid metal post includes a base region adjacent the microelectronic element and a tip region remote from the microelectronic element, the base region and tip region having respective concave circumferential surfaces. Each first solid metal post has a horizontal dimension which is a first function of vertical location in the base region and which is a second function of vertical location in the tip region. | 04-25-2013 |
20130100616 | MULTIPLE DIE STACKING FOR TWO OR MORE DIE - A microelectronic package can include a substrate having first and second opposed surfaces, and first and second microelectronic elements having front surfaces facing the first surface. The substrate can have a plurality of substrate contacts at the first surface and a plurality of terminals at the second surface. Each microelectronic element can have a plurality of element contacts at the front surface thereof. The element contacts can be joined with corresponding ones of the substrate contacts. The front surface of the second microelectronic element can partially overlie a rear surface of the first microelectronic element and can be attached thereto. The element contacts of the first microelectronic element can be arranged in an area array and are flip-chip bonded with a first set of the substrate contacts. The element contacts of the second microelectronic element can be joined with a second set of the substrate contacts by conductive masses. | 04-25-2013 |
20130118784 | HIGH STRENGTH THROUGH-SUBSTRATE VIAS - A component includes a support structure having first and second spaced-apart and parallel surfaces and a plurality of conductive elements extending in a direction between the first and second surfaces. Each conductive element contains an alloy of a wiring metal selected from the group consisting of copper, aluminum, nickel and chromium, and an additive selected from the group consisting of Gallium, Germanium, Indium, Selenium, Tin, Sulfur, Silver, Phosphorus, and Bismuth. The alloy has a composition that varies with distance in at least one direction across the conductive element. A concentration of the additive is less than or equal to 5% of the total atomic mass of the conductive element, and a resistivity of the conductive element is between 2.5 and 30 micro-ohm-centimeter. | 05-16-2013 |
20130122747 | CAVITIES CONTAINING MULTI-WIRING STRUCTURES AND DEVICES - An interconnection component includes an element with an opening, a plurality of conductors electrically insulted from one another extending through the opening, and a plurality of second contacts electrically insulated from one another. The element is comprised of a material having a coefficient of thermal expansion of less than 10 parts per million per degree Celsius. At least some of the conductors extend along at least one inner surface of the opening. The conductors define a plurality of wettable first contacts at the first surface. The first contacts are at least partially aligned with the opening in a direction of the thickness and electrically insulated from one another. | 05-16-2013 |
20130127062 | MULTIPLE DIE FACE-DOWN STACKING FOR TWO OR MORE DIE - A microelectronic assembly can include a substrate having first and second surfaces each extending in first and second transverse directions, a peripheral edge extending in the second direction, first and second openings extending between the first and second surfaces, and a peripheral region of the second surface extending between the peripheral edge and one of the openings. The assembly can also include a first microelectronic element having a front surface facing the first surface, a rear surface opposite therefrom, and an edge extending between the front and rear surfaces. The assembly can also include a second microelectronic element having a front surface facing the rear surface of the first microelectronic element and projecting beyond the edge of the first microelectronic element. The assembly can also include a plurality of terminals exposed at the second surface, at least one of the terminals being disposed at least partially within the peripheral region. | 05-23-2013 |
20130140716 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND REFERENCE WIREBOND - A microelectronic device, e.g., semiconductor chip, is connected with an interconnection element having signal contacts and reference contacts, the reference contacts being connectable to a reference potential such as ground or power. Signal conductors, e.g., signal wirebonds can be connected to device contacts of the microelectronic device, and at least one reference conductor, e.g., reference wirebond can be connected with two reference contacts. The reference wirebond can have a run extending at an at least substantially uniform spacing from an at least a substantial portion of a length of a signal conductor, e.g., signal wirebond. In such manner a desired impedance may be achieved for the signal conductor. | 06-06-2013 |
20130175699 | STACKABLE MICROELECTRONIC PACKAGE STRUCTURES - A microelectronic assembly includes a first microelectronic package having a substrate with first and second opposed surfaces and substrate contacts thereon. The first package further includes first and second microelectronic elements, each having element contacts electrically connected with the substrate contacts and being spaced apart from one another on the first surface so as to provide an interconnect area of the first surface between the first and second microelectronic elements. A plurality of package terminals at the second surface are electrically interconnected with the substrate contacts for connecting the package with a component external thereto. A plurality of stack terminals are exposed at the first surface in the interconnect area for connecting the package with a component overlying the first surface of the substrate. The assembly further includes a second microelectronic package overlying the first microelectronic package and having terminals joined to the stack terminals of the first microelectronic package. | 07-11-2013 |
20130186944 | MICROELECTRONIC SUBSTRATE OR ELEMENT HAVING CONDUCTIVE PADS AND METAL POSTS JOINED THERETO USING BOND LAYER - An interconnection element can include a substrate, e.g., a connection substrate, element of a package, circuit panel or microelectronic substrate, e.g., semiconductor chip, the substrate having a plurality of metal conductive elements such as conductive pads, contacts, bond pads, traces, or the like exposed at the surface. A plurality of solid metal posts may overlie and project away from respective ones of the conductive elements. An intermetallic layer can be disposed between the posts and the conductive elements, such layer providing electrically conductive interconnection between the posts and the conductive elements. Bases of the posts adjacent to the intermetallic layer can be aligned with the intermetallic layer. | 07-25-2013 |
20130203216 | PACKAGE-ON-PACKAGE ASSEMBLY WITH WIRE BONDS TO ENCAPSULATION SURFACE - A method of making a microelectronic package includes forming a dielectric encapsulation layer on an in-process unit having a substrate having a first surface and a second surface remote therefrom. A microelectronic element is mounted to the first surface of the substrate, and a plurality of conductive elements exposed at the first surface, at least some of which are electrically connected to the microelectronic element. Wire bonds have bases joined to the conductive elements and end surfaces remote from the bases and define an edge surface extending away between the base and the end surface. The encapsulation layer is formed to at least partially cover the first surface and portions of the wire bonds with unencapsulated portions of the wire bonds being defined by at least one of the end surface or a portion of the edge surface that is uncovered thereby. | 08-08-2013 |
20130249116 | MICROELECTRONIC PACKAGE - A microelectronic package includes a lower unit having a lower unit substrate with conductive features and a top and bottom surface. The lower unit includes one or more lower unit chips overly/ing the top surface of the lower unit substrate that are electrically connected to the conductive features of the lower unit substrate. The microelectronic package also includes an upper unit including an upper unit substrate having conductive features, top and bottom surfaces and a hole extending between such top and bottom surfaces. The upper unit further includes one or more upper unit chips overlying the top surface of the upper unit substrate and electrically connected to the conductive features of the upper unit substrate by connections extending within the hole. The upper unit may include an upper unit encapsulant that covers the connections of the upper unit and the one or more upper unit chips. | 09-26-2013 |
20130260513 | MICROELECTRONIC PACKAGE WITH TERMINALS ON DIELECTRIC MASS - A package for a microelectronic element | 10-03-2013 |
20130273693 | OFF-CHIP VIAS IN STACKED CHIPS - A microelectronic assembly includes first and second stacked microelectronic elements, each having spaced apart traces extending along a front face and beyond at least a first edge thereof. An insulating region can contact the edges of each microelectronic element and at least portions of the traces of each microelectronic element extending beyond the respective first edges. The insulating region can define first and second side surfaces adjacent the first and second edges of the microelectronic elements. A plurality of spaced apart openings can extend along a side surface of the microelectronic assembly. Electrical conductors connected with respective traces can have portions disposed in respective openings and extending along the respective openings. The electrical conductors may extend to pads or solder balls overlying a face of one of the microelectronic elements. | 10-17-2013 |
20130286707 | STUB MINIMIZATION USING DUPLICATE SETS OF SIGNAL TERMINALS - A microelectronic structure has active elements defining a storage array, and address inputs for receipt of address information specifying locations within the storage array. The structure has a first surface and can have terminals exposed at the first surface. The terminals may include first terminals and the structure may be configured to transfer address information received at the first terminals to the address inputs. Each first terminal can have a signal assignment which includes one or more of the address inputs. The first terminals are disposed on first and second opposite sides of a theoretical plane normal to the first surface, wherein the signal assignments of the first terminals disposed on the first side are a mirror image of the signal assignments of the first terminals disposed on the second side of the theoretical plane. | 10-31-2013 |
20130292834 | MICROELECTRONIC ASSEMBLY WITH JOINED BOND ELEMENTS HAVING LOWERED INDUCTANCE - First and second bond elements, e.g., wire bonds, electrically connect a chip contact with one or more substrate contacts of a substrate, and can be arranged so that the second bond element is joined to the first bond element at each end and so that the second bond element does not touch the chip contact or one or more substrate contacts. A third bond element can be joined to ends of the first and second bond elements. In one embodiment, a bond element can have a looped connection, having first and second ends joined at a first contact and a middle portion joined to a second contact. | 11-07-2013 |
20130299958 | LEAD STRUCTURES WITH VERTICAL OFFSETS - A microelectronic structure includes a first row of contacts ( | 11-14-2013 |
20130300000 | MICROELECTRONIC PACKAGE WITH STACKED MICROELECTRONIC ELEMENTS AND METHOD FOR MANUFACTURE THEREOF - A microelectronic package may include a stacked microelectronic unit including at least first and second vertically stacked microelectronic elements each having a front face facing a top surface of the package. The front face of the first element may be adjacent the top surface, and the first element may overlie the front face of the second element such that at least a portion of the front face of the second element having an element contact thereon extends beyond an edge of the first element. A conductive structure may electrically connect a first terminal at the top surface to an element contact at the front face of the second element, and include a continuous monolithic metal feature extending along the top surface and through at least a portion of an encapsulant, which is between the top surface and the front face of the second element, towards the element contact. | 11-14-2013 |
20130307138 | DESKEWED MULTI-DIE PACKAGES - A microelectronic package may have a plurality of terminals disposed at a face thereof which are configured for connection to at least one external component. e.g., a circuit panel. First and second microelectronic elements can be affixed with packaging structure therein. A first electrical connection can extend from a respective terminal of the package to a corresponding contact on the first microelectronic element, and a second electrical connection can extend from the respective terminal to a corresponding contact on the second microelectronic element, the first and second connections being configured such that a respective signal carried by the first and second connections in each group is subject to propagation delay of the same duration between the respective terminal and each of the corresponding contacts coupled thereto. | 11-21-2013 |
20130313680 | HIGH DENSITY THREE-DIMENSIONAL INTEGRATED CAPACITORS - A component includes a substrate and a capacitor formed in contact with the substrate. The substrate can consist essentially of a material having a coefficient of thermal expansion of less than 10 ppm/° C. The substrate can have a surface and an opening extending downwardly therefrom. The capacitor can include at least first and second pairs of electrically conductive plates and first and second electrodes. The first and second pairs of plates can be connectable with respective first and second electric potentials. The first and second pairs of plates can extend along an inner surface of the opening, each of the plates being separated from at least one adjacent plate by a dielectric layer. The first and second electrodes can be exposed at the surface of the substrate and can be coupled to the respective first and second pairs of plates. | 11-28-2013 |
20130328186 | REDUCED STRESS TSV AND INTERPOSER STRUCTURES - A component can include a substrate and a conductive via extending within an opening in the substrate. The substrate can have first and second opposing surfaces. The opening can extend from the first surface towards the second surface and can have an inner wall extending away from the first surface. A dielectric material can be exposed at the inner wall. The conductive via can define a relief channel within the opening adjacent the first surface. The relief channel can have an edge within a first distance from the inner wall in a direction of a plane parallel to and within five microns below the first surface, the first distance being the lesser of one micron and five percent of a maximum width of the opening in the plane. The edge can extend along the inner wall to span at least five percent of a circumference of the inner wall. | 12-12-2013 |
20130330905 | EDGE CONNECT WAFER LEVEL STACKING - A method of making a stacked microelectronic package by forming a microelectronic assembly by stacking a first subassembly including a plurality of microelectronic elements onto a second subassembly including a plurality of microelectronic elements, at least some of the plurality of microelectronic elements of said first subassembly and said second subassembly having traces that extend to respective edges of the microelectronic elements, then forming notches in the microelectronic assembly so as to expose the traces of at least some of the plurality of microelectronic elements, then forming leads at the side walls of the notches, the leads being in electrical communication with at least some of the traces and dicing the assembly into packages. Additional embodiments include methods for creating stacked packages using substrates and having additional traces that extend to both the top and bottom of the package. | 12-12-2013 |
20130334698 | MICROELECTRONIC ASSEMBLY TOLERANT TO MISPLACEMENT OF MICROELECTRONIC ELEMENTS THEREIN - A microelectronic assembly tolerant to misplacement of microelectronic elements therein may include a molded structure containing a plurality of microelectronic elements. Each microelectronic element has elements contacts having first and second dimensions in respective first and second directions that are transverse to each other, where the first dimension is at least twice the second dimension. In addition, the assembly may include a conductive redistribution layer including conductive vias extending through a dielectric layer to the element contacts of the respective microelectronic elements, where the conductive vias have a third dimension in a third direction and a fourth dimension in a fourth direction, and where the fourth direction is transverse to the third and first directions and the fourth dimension is greater than the third dimension. | 12-19-2013 |
20130341299 | Method of Making a Microelectronic Interconnect Element With Decreased Conductor Spacing - A microelectronic interconnect element can include a plurality of first metal lines and a plurality of second metal lines interleaved with the first metal lines. Each of the first and second metal lines has a surface extending within the same reference plane. The first metal lines have surfaces above the reference plane and remote therefrom and the second metal lines have surfaces below the reference plane and remote therefrom. A dielectric layer can separate a metal line of the first metal lines from an adjacent metal line of the second metal lines. | 12-26-2013 |
20130341804 | SIMULTANEOUS WAFER BONDING AND INTERCONNECT JOINING - Disclosed are a microelectronic assembly of two elements and a method of forming same. A microelectronic element includes a major surface, and a dielectric layer and at least one bond pad exposed at the major surface. The microelectronic element may contain a plurality of active circuit elements. A first metal layer is deposited overlying the at least one bond pad and the dielectric layer. A second element having a second metal layer deposited thereon is provided, and the first metal layer is joined with the second metal layer. The assembly may be severed along dicing lanes into individual units each including a chip. | 12-26-2013 |
20130344652 | RECONSTITUTED WAFER STACK PACKAGING WITH AFTER-APPLIED PAD EXTENSIONS - A stacked microelectronic unit is provided which can include a plurality of vertically stacked microelectronic elements each having a front surface, contacts exposed at the front surface, a rear surface and edges extending between the front and rear surfaces. Traces connected with the contacts may extend along the front surfaces towards edges of the microelectronic elements with the rear surface of at least one of the stacked microelectronic elements being adjacent to a top face of the microelectronic unit. A plurality of conductors may extend along edges of the microelectronic elements from the traces to the top face. The conductors may be conductively connected with unit contacts such that the unit contacts overlie the rear surface of the at least one microelectronic element adjacent to the top face. | 12-26-2013 |
20130344682 | STACKED PACKAGING IMPROVEMENTS - A plurality of microelectronic assemblies ( | 12-26-2013 |
20140021641 | MICROELECTRONIC PACKAGES HAVING CAVITIES FOR RECEIVING MICROELECTRONIC ELEMENTS - Packaged microelectronic elements are provided which include a dielectric element, a cavity, a plurality of chip contacts and a plurality of package contacts, and microelectronic elements having a plurality of bond pads connected to the chip contacts. | 01-23-2014 |
20140035121 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND IMPROVED THERMAL CHARACTERISTICS - A microelectronic assembly includes a dielectric element that has oppositely-facing first and second surfaces and first and second apertures extending between the surfaces. The dielectric element further includes conductive elements. First and second microelectronic elements are stacked one on top of the another. The second microelectronic element has a plurality of contacts at a surface, which is spaced from the first surface of the dielectric element. Leads extend from contacts of the first and second microelectronic elements through respective apertures to at least some of the conductive elements. A heat spreader is thermally coupled to at least one of the first microelectronic element or the second microelectronic element. | 02-06-2014 |
20140036454 | BVA INTERPOSER - A method for making an interposer includes forming a plurality of wire bonds bonded to one or more first surfaces of a first element. A dielectric encapsulation is formed contacting an edge surface of the wire bonds which separates adjacent wire bonds from one another. Further processing comprises removing at least portions of the first element, wherein the interposer has first and second opposite sides separated from one another by at least the encapsulation, and the interposer having first contacts and second contacts at the first and second opposite sides, respectively, for electrical connection with first and second components, respectively, the first contacts being electrically connected with the second contacts through the wire bonds. | 02-06-2014 |
20140038363 | TSOP WITH IMPEDANCE CONTROL - A semiconductor device of an illustrative embodiment includes a die, a lead frame including a plurality of leads having substantial portions arranged in a lead plane and electrically connected to the die. Most preferably, the package includes at least a substantial portion of one conductive element arranged in a plane positioned adjacent the lead frame and substantially parallel to the lead plane, the conductive element being capacitively coupled to the leads such that the conductive element and at least one of the leads cooperatively define a controlled-impedance conduction path, and an encapsulant which encapsulates the leads and the conductive element. The leads and, desirably, the conductive element have respective connection regions which are not covered by the encapsulant. | 02-06-2014 |
20140042644 | FLIP-CHIP, FACE-UP AND FACE-DOWN WIREBOND COMBINATION PACKAGE - A microelectronic assembly can include a substrate having an aperture extending between first and second surfaces thereof, the substrate having substrate contacts at the first surface and terminals at the second surface. The microelectronic assembly can include a first microelectronic element having a front surface facing the first surface, a second microelectronic element having a front surface facing the first microelectronic element, and leads electrically connecting the contacts of the second microelectronic element with the terminals. The second microelectronic element can have contacts exposed at the front surface thereof beyond an edge of the first microelectronic element. The first microelectronic element can be configured to regenerate at least some signals received by the microelectronic assembly at the terminals and to transmit said signals to the second microelectronic element. The second microelectronic element can embody a greater number of active devices to provide memory storage array function than any other function. | 02-13-2014 |
20140048954 | STACKED MICROELECTRONIC ASSEMBLY WITH TSVS FORMED IN STAGES WITH PLURAL ACTIVE CHIPS - A microelectronic assembly is provided in which first and second electrically conductive pads exposed at front surfaces of first and second microelectronic elements, respectively, are juxtaposed, each of the microelectronic elements embodying active semiconductor devices. An electrically conductive element may extend within a first opening extending from a rear surface of the first microelectronic element towards the front surface thereof, within a second opening extending from the first opening towards the front surface of the first microelectronic element, and within a third opening extending through at least one of the first and second pads to contact the first and second pads. Interior surfaces of the first and second openings may extend in first and second directions relative to the front surface of the first microelectronic element, respectively, to define a substantial angle. | 02-20-2014 |
20140055941 | CO-SUPPORT SYSTEM AND MICROELECTRONIC ASSEMBLY - A system may include a microelectronic assembly having terminals and a microelectronic element, and a component for connection with the microelectronic assembly. The component may include a support structure bearing conductors configured to carry command and address information, and contacts coupled to the conductors and connected with the terminals of the microelectronic assembly. The contacts may have address and command information assignments arranged according to a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the contacts at a first sampling rate, and according to a second predetermined arrangement for connection with a second type of microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the contacts at a second sampling rate greater than the first sampling rate. | 02-27-2014 |
20140055942 | CO-SUPPORT MODULE AND MICROELECTRONIC ASSEMBLY - A module may be configured for connection with a microelectronic assembly having terminals and a microelectronic element. The module may include a circuit panel bearing conductors configured to carry command and address information, co-support contacts coupled to the conductors, and module contacts coupled to the conductors. The co-support contacts may include first contacts having address and command information assignments arranged according to a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the first contacts at a first sampling rate, and according to a second predetermined arrangement for connection with a second type of the microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the first contacts at a second sampling rate greater than the first sampling rate. | 02-27-2014 |
20140055970 | CO-SUPPORT COMPONENT AND MICROELECTRONIC ASSEMBLY - A component may be configured for connection with a microelectronic assembly having terminals and a microelectronic element connected with the terminals. The component may include a support structure bearing conductors configured to carry command and address information, and a plurality of contacts coupled to the conductors and configured for connection with the terminals. The contacts may have address and command information assignments arranged according to a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the contacts at a first sampling rate, and according to a second predetermined arrangement for connection with a second type of microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the contacts at a second sampling rate greater than the first sampling rate. | 02-27-2014 |
20140057370 | DUAL WAFER SPIN COATING - A method of bonding a first substrate and a second substrate includes the steps of rotating first substrate with an adhesive mass thereon, and second substrate contacting the mass and overlying the first substrate, controlling a vertical height of a heated control platen spaced apart from and not contacting the second substrate so as to control a temperature of the adhesive mass, so as to at least one of bond the first and second substrates in alignment with one another, or achieve a sufficiently planar adhesive interface between the first and second substrates. | 02-27-2014 |
20140077351 | MICROELECTRONIC PACKAGES WITH NANOPARTICLE JOINING - A method of making an assembly includes the steps of applying metallic nanoparticles to exposed surfaces of conductive elements of either of or both of a first component and a second component, juxtaposing the conductive elements of the first component with the conductive elements of the second component with the metallic nanoparticles disposed therebetween, and elevating a temperature at least at interfaces of the juxtaposed conductive elements to a joining temperature at which the metallic nanoparticles cause metallurgical joints to form between the juxtaposed conductive elements. The conductive elements of either of or both of the first component and the second component can include substantially rigid posts having top surfaces projecting a height above the surface of the respective component and edge surfaces extending at substantial angles away from the top surfaces thereof. | 03-20-2014 |
20140084485 | RELIABLE PACKAGING AND INTERCONNECT STRUCTURES - Methods and apparatus for forming a semiconductor device are provided which may include any number of features. One feature is a method of forming an interconnect structure that results in the interconnect structure having a top surface and portions of the side walls of the interconnect structure covered in a dissimilar material. In some embodiments, the dissimilar material can be a conductive material or a nano-alloy. The interconnect structure can be formed by removing a portion of the interconnect structure, and covering the interconnect structure with the dissimilar material. The interconnect structure can comprise a damascene structure, such as a single or dual damascene structure, or alternatively, can comprise a silicon-through via (TSV) structure. | 03-27-2014 |
20140097546 | MULTI-FUNCTION AND SHIELDED 3D INTERCONNECTS - A microelectronic unit includes a semiconductor element consisting essentially of semiconductor material and having a front surface, a rear surface, a plurality of active semiconductor devices adjacent the front surface, a plurality of conductive pads exposed at the front surface, and an opening extending through the semiconductor element. At least one of the conductive pads can at least partially overlie the opening and can be electrically connected with at least one of the active semiconductor devices. The microelectronic unit can also include a first conductive element exposed at the rear surface for connection with an external component, the first conductive element extending through the opening and electrically connected with the at least one conductive pad, and a second conductive element extending through the opening and insulated from the first conductive element. The at least one conductive pad can overlie a peripheral edge of the second conductive element. | 04-10-2014 |
20140099754 | COMPLIANT INTERCONNECTS IN WAFERS - A microelectronic assembly includes a substrate and an electrically conductive element. The substrate can have a CTE less than 10 ppm/° C., a major surface having a recess not extending through the substrate, and a material having a modulus of elasticity less than 10 GPa disposed within the recess. The electrically conductive element can include a joining portion overlying the recess and extending from an anchor portion supported by the substrate. The joining portion can be at least partially exposed at the major surface for connection to a component external to the microelectronic unit. | 04-10-2014 |
20140103500 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND CONDUCTIVE REFERENCE ELEMENT - A microelectronic assembly can include a microelectronic device having device contacts exposed at a surface thereof and an interconnection element having element contacts and having a face adjacent to the microelectronic device. Conductive elements, e.g., wirebonds connect the device contacts with the element contacts and have portions extending in runs above the surface of the microelectronic device. A conductive layer has a conductive surface disposed at at least a substantially uniform distance above or below the plurality of the runs of the conductive elements. In some cases, the conductive material can have first and second dimensions in first and second horizontal directions which are smaller than first and second corresponding dimensions of the microelectronic device. The conductive material is connectable to a source of reference potential so as to achieve a desired impedance for the conductive elements. | 04-17-2014 |
20140103535 | STUB MINIMIZATION FOR ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic package can include a substrate and a microelectronic element having a face and one or more columns of contacts thereon which face and are joined to corresponding contacts on a surface of the substrate. An axial plane may intersect the face along a line in the first direction and centered relative to the columns of element contacts. Columns of package terminals can extend in the first direction. First terminals in a central region of the second surface can be configured to carry address information usable to determine an addressable memory location within the microelectronic element. The central region may have a width not more than three and one-half times a minimum pitch between the columns of package terminals. The axial plane can intersect the central region. | 04-17-2014 |
20140110832 | CO-SUPPORT CIRCUIT PANEL AND MICROELECTRONIC PACKAGES - A circuit panel can include contacts exposed at a connection site of a major surface thereof and configured to be coupled to terminals of a microelectronic package. The connection site can define a peripheral boundary on the major surface surrounding a group of the contacts that is configured to be coupled to a single microelectronic package. The group of contacts can include first, second, third, and fourth sets of first contacts. Signal assignments of the first and third sets of first contacts can be symmetric about a theoretical plane normal to the major surface with signal assignments of the respective second and fourth sets of first contacts. Each of the sets of first contacts can be configured to carry identical signals. Each of the sets of first contacts can be configured to carry address information sufficient to specify a location within a memory storage array of the microelectronic package. | 04-24-2014 |
20140117516 | MULTIPLE DIE IN A FACE DOWN PACKAGE - A microelectronic package includes a subassembly including a first substrate and first and second microelectronic elements having contact-bearing faces facing towards oppositely-facing first and second surfaces of the first substrate and each having contacts electrically connected with the first substrate. The contact-bearing faces of the first and second microelectronic elements at least partially overlie one another. Leads electrically connect the subassembly with a second substrate, at least portions of the leads being aligned with an aperture in the second substrate. The leads can include wire bonds extending through an aperture in the first substrate and joined to contacts of the first microelectronic element aligned with the first substrate aperture. In one example, the subassembly can be electrically connected with the second substrate using electrically conductive spacer elements. | 05-01-2014 |
20140117567 | MICROELECTRONIC ASSEMBLY WITH IMPEDANCE CONTROLLED WIREBOND AND REFERENCE WIREBOND - A microelectronic assembly can include a microelectronic device, e.g., semiconductor chip, connected together with an interconnection element, e.g., substrate, the latter having signal contacts and reference contacts. The reference contacts can be connectable to a source of reference potential such as ground or a voltage source other than ground such as a voltage source used for power. Signal conductors, e.g., signal wirebonds can be connected to device contacts exposed at a surface of the microelectronic device. Reference conductors, e.g., reference wirebonds can be provided, at least one of which can be connected with two reference contacts of the interconnection element. The reference wirebond can have a run which extends at an at least substantially uniform spacing from a signal conductor, e.g., signal wirebond that is connected to the microelectronic device over at least a substantial portion of the length of the signal conductor. In such manner a desired impedance may be achieved for the signal conductor. | 05-01-2014 |
20140124565 | MICROELECTRONIC ASSEMBLY WITH JOINED BOND ELEMENTS HAVING LOWERED INDUCTANCE - First and second bond elements, e.g., wire bonds, electrically connect a chip contact with one or more substrate contacts of a substrate, and can be arranged so that the second bond element is joined to the first bond element at each end and so that the second bond element does not touch the chip contact or one or more substrate contacts. A third bond element can be joined to ends of the first and second bond elements. In one embodiment, a bond element can have a looped connection, having first and second ends joined at a first contact and a middle portion joined to a second contact. | 05-08-2014 |
20140131849 | STACKED CHIP-ON-BOARD MODULE WITH EDGE CONNECTOR - A module can include a module card and first and second microelectronic elements having front surfaces facing a first surface of the module card. The module card can also have a second surface and a plurality of parallel exposed edge contacts adjacent an edge of at least one of the first and second surfaces for mating with corresponding contacts of a socket when the module is inserted in the socket. Each microelectronic element can be electrically connected to the module card. The front surface of the second microelectronic element can partially overlie a rear surface of the first microelectronic element and can be attached thereto. | 05-15-2014 |
20140131851 | STRUCTURE FOR MICROELECTRONIC PACKAGING WITH TERMINALS ON DIELECTRIC MASS - A structure may include a spacer element overlying a first portion of a first surface of a substrate; first terminals at a second surface of the substrate opposite the first surface; and second terminals overlying a third surface of the spacer element facing away from the first surface. Traces extend from the second terminals along an edge surface of the spacer element that extends from the third surface towards the first surface, and may be electrically coupled between the second terminals and the first terminals or electrically conductive elements at the first surface. The spacer element may at least partially define a second portion of the first surface, which is other than the first portion and has an area sized to accommodate an entire area of a microelectronic element. Some of the conductive elements are at the second portion and may permit connection with such microelectronic element. | 05-15-2014 |
20140131875 | Z-CONNECTION USING ELECTROLESS PLATING - In one embodiment, an assembly includes a substrate having a substrate conductor and a contact at a first surface and a terminal at a second surface for electrically interconnecting the assembly with a component external to the assembly, at least one of the substrate conductor or the contact being electrically connected with the terminal; a first element having a first surface facing the first surface of the substrate and having a first conductor at the first surface and a second conductor at a second surface, an interconnect structure extending through the first element electrically connecting the first and second conductors; an adhesive layer bonding the first surfaces of the first element and the substrate, at least portions of the first conductor and the substrate conductor being disposed beyond an edge of the adhesive layer; and a continuous electroless plated metal region extending between the first conductor and the substrate conductor. | 05-15-2014 |
20140131892 | CHIP ASSEMBLY HAVING VIA INTERCONNECTS JOINED BY PLATING - An assembly and method of making same are provided. The assembly can be formed by juxtaposing a first electrically conductive element overlying a major surface of a first semiconductor element with an electrically conductive pad exposed at a front surface of a second semiconductor element. An opening can be formed extending through the conductive pad of the second semiconductor element and exposing a surface of the first conductive element. The opening may alternatively be formed extending through the first conductive element. A second electrically conductive element can be formed extending at least within the opening and electrically contacting the conductive pad and the first conductive element. A third semiconductor element can be positioned in a similar manner with respect to the second semiconductor element. | 05-15-2014 |
20140131900 | MICROELECTRONIC ASSEMBLY WITH THERMALLY AND ELECTRICALLY CONDUCTIVE UNDERFILL - A microelectronic assembly may include a microelectronic element having a surface and a plurality of contacts at the surface; a first element consisting essentially of at least one of semiconductor or dielectric material, the first element having a surface facing the surface of the microelectronic element and a plurality of first element contacts at the surface of the first element; electrically conductive masses each joining a contact of the plurality of contacts of the microelectronic element with a respective first element contact of the plurality of first element contacts; a thermally and electrically conductive material layer between the surface of the microelectronic element and the surface of the first element and adjacent conductive masses of the conductive masses; and an electrically insulating coating electrically insulating the conductive masses and the surfaces of the microelectronic element and the first element from the thermally and electrically conductive material layer | 05-15-2014 |
20140145329 | FINE PITCH MICROCONTACTS AND METHOD FOR FORMING THEREOF - A method includes applying a final etch-resistant material to an in-process substrate so that the final etch-resistant material at least partially covers first microcontact portions integral with the substrate and projecting upwardly from a surface of the substrate, and etching the surface of the substrate so as to leave second microcontact portions below the first microcontact portions and integral therewith, the final etch-resistant material at least partially protecting the first microcontact portions from etching during the further etching step. A microelectronic unit includes a substrate, and a plurality of microcontacts projecting in a vertical direction from the substrate, each microcontact including a base region adjacent the substrate and a tip region remote from the substrate, each microcontact having a horizontal dimension which is a first function of vertical location in the base region and which is a second function of vertical location in the tip region. | 05-29-2014 |
20140159248 | HIGH PERFORMANCE PACKAGE ON PACKAGE - A microelectronic assembly can include a first package comprising a processor and a second package electrically connected to the first package. The second package can include two or more microelectronic elements each having memory storage array function and contacts at a respective element face, upper and lower opposite package faces, upper and lower terminals at the respective upper and lower package faces, and electrically conductive structure extending through the second package. At least portions of edges of respective microelectronic elements of the two or more microelectronic elements can be spaced apart from one another, so as to define a central region between the edges that does not overlie any of the element faces of the microelectronic elements of the second package. The electrically conductive structure can be aligned with the central region and can electrically connect the lower terminals with at least one of: the upper terminals or the contacts. | 06-12-2014 |
20140167267 | METHOD AND STRUCTURES FOR HEAT DISSIPATING INTERPOSERS - A method for making an interconnect element includes depositing a thermally conductive layer on an in-process unit. The in-process unit includes a semiconductor material layer defining a surface and edges surrounding the surface, a plurality of conductive elements, each conductive element having a first portion extending through the semiconductor material layer and a second portion extending from the surface of the semiconductor material layer. Dielectric coatings extend over at least the second portion of each conductive element. The thermally conductive layer is deposited on the in-process unit at a thickness of at least 10 microns so as to overlie a portion of the surface of the semiconductor material layer between the second portions of the conductive elements with the dielectric coatings positioned between the conductive elements and the thermally conductive layer. | 06-19-2014 |
20140167278 | STUB MINIMIZATION USING DUPLICATE SETS OF TERMINALS FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic assembly can include a microelectronic package connected with a circuit panel. The package has a microelectronic element having a front face facing away from a substrate of the package, and electrically connected with the substrate through conductive structure extending above the front face. First terminals provided in first and second parallel grids or in first and second individual columns can be configured to carry address information usable to determine an addressable memory location from among all the available addressable memory locations of the memory storage array. The first terminals in the first grid can have signal assignments which are a mirror image of the signal assignments of the first terminals in the second grid. | 06-19-2014 |
20140167279 | STUB MINIMIZATION USING DUPLICATE SETS OF SIGNAL TERMINALS IN ASSEMBLIES WITHOUT WIREBONDS TO PACKAGE SUBSTRATE - A microelectronic assembly can include a circuit panel having first and second panel contacts at respective first and second surfaces thereof, and first and second microelectronic packages each having terminals mounted to the respective panel contacts. Each package can include a microelectronic element having a face and contacts thereon, a substrate having first and second surfaces, and terminals on the second surface configured for connecting the package with an external component. The terminals can include first terminals at positions within first and second parallel grids. The first terminals can be configured to carry address information usable by circuitry within the package to determine an addressable memory location from among all the available addressable memory locations of a memory storage array within the microelectronic element. Signal assignments of the first terminals in the first grid can be a mirror image of signal assignments of the first terminals in the second grid. | 06-19-2014 |
20140167287 | MICROELECTRONIC PACKAGE WITH TERMINALS ON DIELECTRIC MASS - A package for a microelectronic element, such as a semiconductor chip, has a dielectric mass overlying the package substrate and microelectronic element and has top terminals exposed at the top surface of the dielectric mass. Traces extending along edge surfaces of the dielectric mass desirably connect the top terminals to bottom terminals on the package substrate. The dielectric mass can be formed, for example, by molding or by application of a conformal layer. | 06-19-2014 |
20140175654 | SURFACE MODIFIED TSV STRUCTURE AND METHODS THEREOF - Microelectronic elements and methods of their manufacture are disclosed. A microelectronic element may include a substrate including an opening extending through a semiconductor region of the substrate, a dielectric layer cover a wall of the opening within at least a first portion of the opening, a first metal disposed within the first portion of the opening, a second metal disposed within a second portion of the opening. The second metal may form at least part of a contact of the microelectronic element. | 06-26-2014 |
20140175671 | STRUCTURE FOR MICROELECTRONIC PACKAGING WITH BOND ELEMENTS TO ENCAPSULATION SURFACE - A structure may include bond elements having bases joined to conductive elements at a first portion of a first surface and end surfaces remote from the substrate. A dielectric encapsulation element may overlie and extend from the first portion and fill spaces between the bond elements to separate the bond elements from one another. The encapsulation element has a third surface facing away from the first surface. Unencapsulated portions of the bond elements are defined by at least portions of the end surfaces uncovered by the encapsulation element at the third surface. The encapsulation element at least partially defines a second portion of the first surface that is other than the first portion and has an area sized to accommodate an entire area of a microelectronic element. Some conductive elements are at the second portion and configured for connection with such microelectronic element. | 06-26-2014 |
20140179061 | THIN WAFER HANDLING - A first area of a first surface of an encapsulated component can be thinned, the component including: a semiconductor chip having an active surface opposite the first surface, and an encapsulant extending outwardly from edges of the semiconductor chip. An entire area of the active surface may be aligned with the first area. After the abrading, a second area of the encapsulated component beyond the first area may have a thickness greater than a thickness of the first area. The second area can be configured to fully support the abraded encapsulated component in a state of the encapsulated component being manipulated by handling equipment. | 06-26-2014 |
20140185354 | STUB MINIMIZATION USING DUPLICATE SETS OF SIGNAL TERMINALS - A microelectronic structure has active elements defining a storage array, and address inputs for receipt of address information specifying locations within the storage array. The structure has a first surface and can have terminals exposed at the first surface. The terminals may include first terminals and the structure may be configured to transfer address information received at the first terminals to the address inputs. Each first terminal can have a signal assignment which includes one or more of the address inputs. The first terminals are disposed on first and second opposite sides of a theoretical plane normal to the first surface, wherein the signal assignments of the first terminals disposed on the first side are a mirror image of the signal assignments of the first terminals disposed on the second side of the theoretical plane. | 07-03-2014 |
20140199811 | STACKABLE MICROELECTRONIC PACKAGE STRUCTURES - A microelectronic assembly includes a first microelectronic package having a substrate with first and second opposed surfaces and substrate contacts thereon. The first package further includes first and second microelectronic elements, each having element contacts electrically connected with the substrate contacts and being spaced apart from one another on the first surface so as to provide an interconnect area of the first surface between the first and second microelectronic elements. A plurality of package terminals at the second surface are electrically interconnected with the substrate contacts for connecting the package with a component external thereto. A plurality of stack terminals are exposed at the first surface in the interconnect area for connecting the package with a component overlying the first surface of the substrate. The assembly further includes a second microelectronic package overlying the first microelectronic package and having terminals joined to the stack terminals of the first microelectronic package. | 07-17-2014 |
20140203452 | ACTIVE CHIP ON CARRIER OR LAMINATED CHIP HAVING MICROELECTRONIC ELEMENT EMBEDDED THEREIN - A structure including a first semiconductor chip with front and rear surfaces and a cavity in the rear surface. A second semiconductor chip is mounted within the cavity. The first chip may have vias extending from the cavity to the front surface and via conductors within these vias serving to connect the additional microelectronic element to the active elements of the first chip. The structure may have a volume comparable to that of the first chip alone and yet provide the functionality of a multi-chip assembly. A composite chip incorporating a body and a layer of semiconductor material mounted on a front surface of the body similarly may have a cavity extending into the body from the rear surface and may have an additional microelectronic element mounted in such cavity. | 07-24-2014 |
20140206147 | STACKED MICROELECTRONIC ASSEMBLY WITH TSVS FORMED IN STAGES AND CARRIER ABOVE CHIP - A microelectronic assembly is provided which includes a first element consisting essentially of at least one of semiconductor or inorganic dielectric material having a surface facing and attached to a major surface of a microelectronic element at which a plurality of conductive pads are exposed, the microelectronic element having active semiconductor devices therein. A first opening extends from an exposed surface of the first element towards the surface attached to the microelectronic element, and a second opening extends from the first opening to a first one of the conductive pads, wherein where the first and second openings meet, interior surfaces of the first and second openings extend at different angles relative to the major surface of the microelectronic element. A conductive element extends within the first and second openings and contacts the at least one conductive pad. | 07-24-2014 |
20140206184 | INTERPOSER HAVING MOLDED LOW CTE DIELECTRIC - A method for making an interconnection component is disclosed, including forming a plurality of metal posts extending away from a reference surface. Each post is formed having a pair of opposed end surface and an edge surface extending therebetween. A dielectric layer is formed contacting the edge surfaces and filling spaces between adjacent ones of the posts. The dielectric layer has first and second opposed surfaces adjacent the first and second end surfaces. The dielectric layer has a coefficient of thermal expansion of less than 8 ppm/° C. The interconnection component is completed such that it has no interconnects between the first and second end surfaces of the posts that extend in a lateral direction. First and second pluralities of wettable contacts are adjacent the first and second opposed surfaces. The wettable contacts are usable to bond the interconnection component to a microelectronic element or a circuit panel. | 07-24-2014 |
20140210104 | NON-LITHOGRAPHIC FORMATION OF THREE-DIMENSIONAL CONDUCTIVE ELEMENTS - A method of forming a conductive element on a substrate and the resulting assembly are provided. The method includes forming a groove in a sacrificial layer overlying a dielectric region disposed on a substrate. The groove preferably extends along a sloped surface of the substrate. The sacrificial layer is preferably removed by a non-photolithographic method, such as ablating with a laser, mechanical milling, or sandblasting. A conductive element is formed in the groove. The grooves may be formed. The grooves and conductive elements may be formed along any surface of the substrate, including within trenches and vias formed therein, and may connect to conductive pads on the front and/or rear surface of the substrate. The conductive elements are preferably formed by plating and may or may not conform to the surface of the substrate. | 07-31-2014 |
20140213021 | MICROELECTRONIC PACKAGES AND METHODS THEREFOR - A method of making a microelectronic assembly can include molding a dielectric material around at least two conductive elements which project above a height of a substrate having a microelectronic element mounted thereon, so that remote surfaces of the conductive elements remain accessible and exposed within openings extending from an exterior surface of the molded dielectric material. The remote surfaces can be disposed at heights from said surface of said substrate which are lower or higher than a height of the exterior surface of the molded dielectric material from the substrate surface. The conductive elements can be arranged to simultaneously carry first and second different electric potentials: e.g., power, ground or signal potentials. | 07-31-2014 |
20140217584 | FLOW UNDERFILL FOR MICROELECTRONIC PACKAGES - A microelectronic assembly includes a first component with first conductive elements; a second component with second conductive elements; a bond metal; and an underfill layer. The posts have a height above the respective surface from which the posts project. A bond metal can be disposed between respective pairs of conductive elements, each pair including at least one of the posts and at least one of the first or second conductive elements confronting the at least one post. The bond metal can contact edges of the posts along at least one half the height of the posts. An underfill layer contacts and bonds the first and second surfaces of the first and second components. A residue of the underfill layer may be present at at least one interfacial surfaces between at least some of the posts and the bond metal or may be present within the bond metal. | 08-07-2014 |
20140217607 | REDUCED STRESS TSV AND INTERPOSER STRUCTURES - A component can include a substrate and a conductive via extending within an opening in the substrate. The substrate can have first and second opposing surfaces. The opening can extend from the first surface towards the second surface and can have an inner wall extending away from the first surface. A dielectric material can be exposed at the inner wall. The conductive via can define a relief channel within the opening adjacent the first surface. The relief channel can have an edge within a first distance from the inner wall in a direction of a plane parallel to and within five microns below the first surface, the first distance being the lesser of one micron and five percent of a maximum width of the opening in the plane. The edge can extend along the inner wall to span at least five percent of a circumference of the inner wall. | 08-07-2014 |
20140217617 | MULTI-DIE WIREBOND PACKAGES WITH ELONGATED WINDOWS - A microelectronic package can include a substrate having first and second opposed surfaces extending in first and second transverse directions and an opening extending between the first and second surfaces and defining first and second distinct parts each elongated along a common axis extending in the first direction, first and second microelectronic elements each having a front surface facing the first surface of the substrate and a column of contacts at the respective front surface, a plurality of terminals exposed at the second surface, and first and second electrical connections aligned with the respective first and second parts of the opening and extending from at least some of the contacts of the respective first and second microelectronic elements to at least some of the terminals. The column of contacts of the first and second microelectronic elements can be aligned with the respective first and second parts of the opening. | 08-07-2014 |
20140239491 | MICROELECTRONIC UNIT AND PACKAGE WITH POSITIONAL REVERSAL - A semiconductor unit includes a chip having left and right columns of contacts at its front surface. Interconnect pads are provided overlying the front surface of the chip and connected to at least some of the contacts as, for example, by traces or by arrangements including wire bonds. The interconnect pads alone, or the interconnect pads and some of the contacts, provide an array of external connection elements. This array includes some reversal pairs of external connection elements in which the external connection element connected to or incorporating the right contact is disposed to the left of the external connection element incorporating or connected to the left contact. Such a unit may be used in a multi-chip. The reversed connections simplify routing, particularly where corresponding contacts of two chips are to be connected to common terminals on the package substrate. | 08-28-2014 |
20140239513 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS - A microelectronic assembly includes a dielectric element having first and second surfaces, first and second apertures extending between the first and second surfaces and defining a central region of the first surface between the first and second apertures, first and second microelectronic elements, and leads extending from contacts exposed at respective front surfaces of the first and second microelectronic elements to central terminals exposed at the central region. The front surface of the first microelectronic element can face the second surface of the dielectric element. The front surface of the second microelectronic element can face a rear surface of the first microelectronic element. The contacts of the second microelectronic element can project beyond an edge of the first microelectronic element. At least first and second ones of the leads can electrically interconnect a first central terminal of the central terminals with each of the first and second microelectronic elements. | 08-28-2014 |
20140239514 | MICROELECTRONIC PACKAGE WITH CONSOLIDATED CHIP STRUCTURES - A chip package has multiple chips that may be arranged side-by-side or in a staggered, stair step arrangement. The contacts of the chips are connected to interconnect pads carried on the chips themselves or on a redistribution substrate. The interconnect pads desirably are arranged in a relatively narrow interconnect zone, such that the interconnect pads can be readily wire-bonded or otherwise connected to a package substrate. | 08-28-2014 |
20140262457 | POROUS ALUMINA TEMPLATES FOR ELECTRONIC PACKAGES - Interposers and methods of making the same are disclosed herein. In one embodiment, an interposer includes a region having first and second oppositely facing surfaces and a plurality of pores, each pore extending in a first direction from the first surface towards the second surface, wherein alumina extends along a wall of each pore; a plurality of electrically conductive connection elements extending in the first direction, consisting essentially of aluminum and being electrically isolated from one another by at least the alumina; a first conductive path provided at the first surface for connection with a first component external to the interposer; and a second conductive path provided at the second surface for connection with a second component external to the interposer, wherein the first and second conductive paths are electrically connected through at least some of the connection elements. | 09-18-2014 |
20140262460 | Connection Component with Posts and Pads - A packaged microelectronic element includes connection component incorporating a dielectric layer ( | 09-18-2014 |
20140264730 | MICROELECTRONIC ELEMENTS WITH MASTER/SLAVE CONFIGURABILITY - A semiconductor chip that may be configured to function as either a master chip or a slave chip. The semiconductor chip may be included in a microelectronic assembly including a plurality of vertically stacked semiconductor chips, with each of the chips containing functional circuit blocks that enable each semiconductor chip to function as either a master chip or a slave chip under in accordance with a state input stored on the same chip, or received from another chip in the stacked assembly or from another component of a system in which the stacked assembly is configured to operate. | 09-18-2014 |
20140268537 | IN-PACKAGE FLY-BY SIGNALING - In-package fly-by signaling can be provided in a multi-chip microelectronic package having address lines on a package substrate configured to carry address information to a first connection region on the substrate having a first delay from terminals of the package, and the address lines being configured to carry the address information beyond the first connection region to at least to a second connection region having a second delay from the terminals that is greater than the first delay. Address inputs of a first microelectronic element, e.g., semiconductor chip, can be coupled with each of the address lines at the first connection region, and address inputs of a second microelectronic element can be coupled with each of the address lines at the second connection region. | 09-18-2014 |
20140273346 | MANUFACTURE OF FACE-DOWN MICROELECTRONIC PACKAGES - In a high volume method for manufacturing a microelectronic package, a spacer element and a first die, i.e., microelectronic element, can be attached face-down to a surface of a substrate, contacts on the first die facing a first through opening of the substrate. Then, a second die can be attached face-down atop the first die and the spacer element, contacts on the second die disposed beyond an edge of the first die and facing a second through opening in the substrate. Electrical connections can then be formed between each of the first and second dies and the substrate. The first and second dies can be transferred from positions of a single diced wafer which are selected to maximize compound speed bin yield of the microelectronic package. | 09-18-2014 |
20140273393 | HIGH DENSITY THREE-DIMENSIONAL INTEGRATED CAPACITORS - A capacitor can include a substrate having a first surface, a second surface remote from the first surface, and a through opening extending between the first and second surfaces, first and second metal elements, and a capacitor dielectric layer separating and insulating the first and second metal elements from one another at least within the through opening. The first metal element can be exposed at the first surface and can extend into the through opening. The second metal element can be exposed at the second surface and can extend into the through opening. The first and second metal elements can be electrically connectable to first and second electric potentials. The capacitor dielectric layer can have an undulating shape. | 09-18-2014 |
20140291871 | IMPEDANCE CONTROLLED PACKAGES WITH METAL SHEET OR 2-LAYER RDL - A microelectronic assembly is disclosed that is capable of achieving a desired impedance for raised conductive elements. The microelectronic assembly may include an interconnection element, a surface conductive element, a microelectronic device, a plurality of raised conductive elements, and a bond element. The microelectronic device may overlie the dielectric element and at least one surface conductive element attached to the front surface. The plurality of raised conductive elements may connect the device contacts with the element contacts. The raised conductive elements may have substantial portions spaced a first height above and extending at least generally parallel to at least one surface conductive element, such that a desired impedance may be achieved for the raised conductive elements. A bond element may electrically connect at least one surface conductive element with at least one reference contact that may be connectable to a source of reference potential. | 10-02-2014 |
20140319699 | RELIABLE PACKAGING AND INTERCONNECT STRUCTURES - Methods and apparatus for forming a semiconductor device are provided which may include any number of features. One feature is a method of forming an interconnect structure that results in the interconnect structure having a top surface and portions of the side walls of the interconnect structure covered in a dissimilar material. In some embodiments, the dissimilar material can be a conductive material or a nano-alloy. The interconnect structure can be formed by removing a portion of the interconnect structure, and covering the interconnect structure with the dissimilar material. The interconnect structure can comprise a damascene structure, such as a single or dual damascene structure, or alternatively, can comprise a silicon-through via (TSV) structure. | 10-30-2014 |
20140322864 | LOW CTE INTERPOSER - An interconnection component includes a first support portion has a plurality of first conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent a first surface and a second end adjacent a second surface. A second support portion has a plurality of second conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent the first surface and a second end adjacent the second surface. A redistribution layer is disposed between the second surfaces of the first and second support portions, electrically connecting at least some of the first vias with at least some of the second vias. The first and second support portions can have a coefficient of thermal expansion (“CTE”) of less than 12 parts per million per degree, Celsius (“ppm/° C.”). | 10-30-2014 |
20140328015 | STUB MINIMIZATION FOR WIREBOND ASSEMBLIES WITHOUT WINDOWS - A microelectronic assembly ( | 11-06-2014 |
20140328016 | STUB MINIMIZATION FOR MULTI-DIE WIREBOND ASSEMBLIES WITH PARALLEL WINDOWS - A microelectronic assembly | 11-06-2014 |
20140332981 | LOW-STRESS VIAS - A component can include a substrate having a front surface and a rear surface remote therefrom, an opening extending from the rear surface towards the front surface, and a conductive via extending within the opening. The substrate can have a CTE less than 10 ppm/° C. The opening can define an inner surface between the front and rear surfaces. The conductive via can include a first metal layer overlying the inner surface and a second metal region overlying the first metal layer and electrically coupled to the first metal layer. The second metal region can have a CTE greater than a CTE of the first metal layer. The conductive via can have an effective CTE across a diameter of the conductive via that is less than 80% of the CTE of the second metal region. | 11-13-2014 |
20140342503 | COMPLIANT INTERCONNECTS IN WAFERS - A microelectronic assembly includes a substrate and an electrically conductive element. The substrate can have a CTE less than 10 ppm/° C., a major surface having a recess not extending through the substrate, and a material having a modulus of elasticity less than 10 GPa disposed within the recess. The electrically conductive element can include a joining portion overlying the recess and extending from an anchor portion supported by the substrate. The joining portion can be at least partially exposed at the major surface for connection to a component external to the microelectronic unit. | 11-20-2014 |
20140357021 | MULTI-CHIP MODULE WITH STACKED FACE-DOWN CONNECTED DIES - A microelectronic assembly can include a substrate having first and second surfaces, at least two logic chips overlying the first surface, and a memory chip having a front surface with contacts thereon, the front surface of the memory chip confronting a rear surface of each logic chip. The substrate can have conductive structure thereon and terminals exposed at the second surface for connection with a component. Signal contacts of each logic chip can be directly electrically connected to signal contacts of the other logic chips through the conductive structure of the substrate for transfer of signals between the logic chips. The logic chips can be adapted to simultaneously execute a set of instructions of a given thread of a process. The contacts of the memory chip can be directly electrically connected to the signal contacts of at least one of the logic chips through the conductive structure of the substrate. | 12-04-2014 |
20140362629 | SINGLE PACKAGE DUAL CHANNEL MEMORY WITH CO-SUPPORT - A microelectronic package can include a support element having first and second surfaces and substrate contacts at the first or second surface, zeroth and first stacked microelectronic elements electrically coupled with the substrate contacts, and terminals at the second surface electrically coupled with the microelectronic elements. The second surface can have a southwest region encompassing entire lengths of south and west edges of the second surface and extending in orthogonal directions from the south and west edges one-third of each distance toward north and east edges of the second surface, respectively. The terminals can include first terminals at a southwest region of the second surface, the first terminals configured to carry address information usable by circuitry within the microelectronic package to determine an addressable memory location from among all the available addressable memory locations of the memory storage arrays of at least one of the zeroth or first microelectronic elements. | 12-11-2014 |
20140363924 | STACKED MULTI-DIE PACKAGES WITH IMPEDANCE CONTROL - A microelectronic assembly may include microelectronic devices arranged in a stack and having device contacts exposed at respective front surfaces. Signal conductors having substantial portions extending above the front surface of the respective microelectronic devices connect the device contacts with signal contacts of an underlying interconnection element. A rear surface of a microelectronic device of the stack overlying an adjacent microelectronic device of the stack is spaced a predetermined distance above and extends at least generally parallel to the substantial portions of the signal conductors connected to the adjacent device, such that a desired impedance may be achieved for the signal conductors connected to the adjacent device. | 12-11-2014 |
20140367866 | MEMORY MODULE IN A PACKAGE - A microelectronic package can include a substrate having first and second opposed surfaces, at least two pairs of microelectronic elements, and a plurality of terminals exposed at the second surface. Each pair of microelectronic elements can include an upper microelectronic element and a lower microelectronic element. The pairs of microelectronic elements can be fully spaced apart from one another in a horizontal direction parallel to the first surface of the substrate. Each lower microelectronic element can have a front surface facing the first surface of the substrate and a plurality of contacts at the front surface. A surface of each of the upper microelectronic elements can at least partially overlie a rear surface of the lower microelectronic element in its pair. The microelectronic package can also include electrical connections extending from at least some of the contacts of each lower microelectronic element to at least some of the terminals. | 12-18-2014 |
20140376200 | RELIABLE DEVICE ASSEMBLY - Microelectronic assemblies and methods for making the same are disclosed herein. In one embodiment, a method of forming a microelectronic assembly comprises assembling first and second components to have first major surfaces of the first and second components facing one another and spaced apart from one another by a predetermined spacing, the first component having first and second oppositely-facing major surfaces, a first thickness extending in a first direction between the first and second major surfaces, and a plurality of first metal connection elements at the first major surface, the second component having a plurality of second metal connection elements at the first major surface of the second component; and plating a plurality of metal connector regions each connecting and extending continuously between a respective first connection element and a corresponding second connection element opposite the respective first connection element in the first direction. | 12-25-2014 |
20150014847 | MICROELECTRONIC ASSEMBLIES WITH STACK TERMINALS COUPLED BY CONNECTORS EXTENDING THROUGH ENCAPSULATION - A microelectronic assembly or package can include first and second support elements and a microelectronic element between inwardly facing surfaces of the support elements. First connectors and second connectors such as solder balls, metal posts, stud bumps, or the like face inwardly from the respective support elements and are aligned with and electrically coupled with one another in columns. An encapsulation separates respective pairs of coupled first and second connectors from one another and may encapsulate the microelectronic element and fill spaces between the support elements. The first connectors, the second connectors or both may be partially encapsulated prior to electrically coupling respective pairs of first and second connectors in columns. | 01-15-2015 |
20150014856 | MICROELECTRONIC ASSEMBLIES HAVING REINFORCING COLLARS ON CONNECTORS EXTENDING THROUGH ENCAPSULATION - A microelectronic assembly or package can include first and second support elements and a microelectronic element between inwardly facing surfaces of the support elements. First connectors and second connectors such as solder balls, metal posts, stud bumps, or the like face inwardly from the respective support elements and are aligned with and electrically coupled with one another in columns. Dielectric reinforcing collars are provided on outer surfaces of the first connectors, second connectors or both, and an encapsulation separates pairs of coupled connectors from one another and may fill spaces between support elements. | 01-15-2015 |
20150017763 | Microelectronic Assembly With Thermally and Electrically Conductive Underfill - A microelectronic assembly may include a microelectronic element having a surface and a plurality of contacts at the surface; a first element consisting essentially of at least one of semiconductor or dielectric material, the first element having a surface facing the surface of the microelectronic element and a plurality of first element contacts at the surface of the first element; electrically conductive masses each joining a contact of the plurality of contacts of the microelectronic element with a respective first element contact of the plurality of first element contacts; a thermally and electrically conductive material layer between the surface of the microelectronic element and the surface of the first element and adjacent conductive masses of the conductive masses; and an electrically insulating coating electrically insulating the conductive masses and the surfaces of the microelectronic element and the first element from the thermally and electrically conductive material layer | 01-15-2015 |
20150021788 | Multi-Function and Shielded 3D Interconnects - A microelectronic unit includes a semiconductor element consisting essentially of semiconductor material and having a front surface, a rear surface, a plurality of active semiconductor devices adjacent the front surface, a plurality of conductive pads exposed at the front surface, and an opening extending through the semiconductor element. At least one of the conductive pads can at least partially overlie the opening and can be electrically connected with at least one of the active semiconductor devices. The microelectronic unit can also include a first conductive element exposed at the rear surface for connection with an external component, the first conductive element extending through the opening and electrically connected with the at least one conductive pad, and a second conductive element extending through the opening and insulated from the first conductive element. The at least one conductive pad can overlie a peripheral edge of the second conductive element. | 01-22-2015 |
20150028480 | SUBSTRATE AND ASSEMBLY THEREOF WITH DIELECTRIC REMOVAL FOR INCREASED POST HEIGHT - An interconnection substrate includes a plurality of electrically conductive elements of at least one wiring layer defining first and second lateral directions. Electrically conductive projections for bonding to electrically conductive contacts of at least one component external to the substrate, extend from the conductive elements above the at least one wiring layer. The conductive projections have end portions remote from the conductive elements and neck portions between the conductive elements and the end portions. The end portions have lower surfaces extending outwardly from the neck portions in at least one of the lateral directions. The substrate further includes a dielectric layer overlying the conductive elements and extending upwardly along the neck portions at least to the lower surfaces. At least portions of the dielectric layer between the conductive projections are recessed below a height of the lower surfaces. | 01-29-2015 |
20150034371 | STRUCTURE FOR MICROELECTRONIC PACKAGING WITH BOND ELEMENTS TO ENCAPSULATION SURFACE - A structure may include bond elements having bases joined to conductive elements at a first portion of a first surface and end surfaces remote from the substrate. A dielectric encapsulation element may overlie and extend from the first portion and fill spaces between the bond elements to separate the bond elements from one another. The encapsulation element has a third surface facing away from the first surface. Unencapsulated portions of the bond elements are defined by at least portions of the end surfaces uncovered by the encapsulation element at the third surface. The encapsulation element at least partially defines a second portion of the first surface that is other than the first portion and has an area sized to accommodate an entire area of a microelectronic element. Some conductive elements are at the second portion and configured for connection with such microelectronic element. | 02-05-2015 |
20150041208 | MICRO MECHANICAL ANCHOR FOR 3D ARCHITECTURE - Components and methods of making the same are disclosed herein. In one embodiment, a method of forming a component comprises forming metal anchoring elements at a first surface of a support element having first and second oppositely facing surfaces, the support element having a thickness extending in a first direction between the first and second surfaces, wherein each anchoring element has a downwardly facing overhang surface; and then forming posts having first ends proximate the first surface and second ends disposed above the respective first ends and above the first surface, wherein a laterally extending portion of each post contacts at least a first area of the overhang surface of the respective anchoring element and extends downwardly therefrom, and the overhang surface of the anchoring element resists axial and shear forces applied to the posts at positions above the anchoring elements. | 02-12-2015 |
20150043181 | ENHANCED STACKED MICROELECTRONIC ASSEMBLIES WITH CENTRAL CONTACTS AND IMPROVED GROUND OR POWER DISTRIBUTION - The present disclosure is directed to a microelectronic assembly that includes first and second microelectronic elements, signal leads, one or more jumper leads, and a dielectric element that has first and second apertures. The signal leads may be connected to one or more of the microelectronic elements and extend through the one or more of the first or second apertures to conductive elements on the dielectric element. The jumper leads may extend through the first aperture and be connected to a contact of the first microelectronic element. The one or more jumper leads may span over the second aperture and be connected to a conductive element on the dielectric element. | 02-12-2015 |
20150043190 | EMBEDDED PACKAGING WITH PREFORMED VIAS - Microelectronic assemblies and methods of making the same are disclosed. In some embodiments, a microelectronic assembly includes a microelectronic element having edge surfaces bounding a front surface and contacts at the front surface; rigid metal posts disposed between at least one edge surface and a corresponding edge of the assembly, each metal post having a sidewall separating first and second end surfaces, the sidewalls have a root mean square (rms) surface roughness of less than about 1 micron; a encapsulation contacting at least the edge surfaces and the sidewalls; an insulation layer overlying the encapsulation; connection elements extending through the insulation layer, wherein at least some connection elements have cross sections smaller than those of the metal posts; a redistribution structure deposited on the insulation layer and electrically connecting first terminals with corresponding metal posts through the first connection elements, some metal posts electrically coupled with contacts of microelectronic element. | 02-12-2015 |
20150044824 | Fan-Out WLP With Package - The present disclosure is directed to a method for making a microelectronic package that includes assembling a microelectronic unit with a substrate, and electrically connecting redistribution contacts on the microelectronic unit and terminals on the substrate with a conductive matrix material extending within at least one opening extending through the substrate. | 02-12-2015 |
20150048524 | STACKED MICROELECTRONIC PACKAGES HAVING AT LEAST TWO STACKED MICROELECTRONIC ELEMENTS ADJACENT ONE ANOTHER - A microelectronic assembly includes first and second microelectronic elements. Each of the microelectronic elements has oppositely-facing first and second surfaces and edges bounding the surfaces. The first microelectronic element is disposed on the second microelectronic element with the second surface of the first microelectronic element facing toward the first surface of the second microelectronic element. The first microelectronic element preferably extends beyond at least one edge of the second microelectronic element and the second microelectronic element preferably extends beyond at least one edge of the first microelectronic element. A first edge of the first microelectronic element has a length that is smaller than a first edge of the second microelectronic element. A second edge of the first microelectronic element has a length that is greater than the second edge of the second microelectronic element. | 02-19-2015 |
20150076714 | MICROELECTRONIC ELEMENT WITH BOND ELEMENTS TO ENCAPSULATION SURFACE - A microelectronic structure includes a semiconductor having conductive elements at a first surface. Wire bonds have bases joined to the conductive elements and free ends remote from the bases, the free ends being remote from the substrate and the bases and including end surfaces. The wire bonds define edge surfaces between the bases and end surfaces thereof. A compliant material layer extends along the edge surfaces within first portions of the wire bonds at least adjacent the bases thereof and fills spaces between the first portions of the wire bonds such that the first portions of the wire bonds are separated from one another by the compliant material layer. Second portions of the wire bonds are defined by the end surfaces and portions of the edge surfaces adjacent the end surfaces that are extend from a third surface of the compliant later. | 03-19-2015 |
20150079733 | THREE-DIMENSIONAL SYSTEM-IN-A-PACKAGE - A microelectronic assembly can include first, second and third stacked substantially planar elements, e.g., of dielectric or semiconductor material, and which may have a CTE of less than 10 ppm/° C. The assembly may be a microelectronic package and may incorporate active semiconductor devices in one, two or more of the first, second or third elements to function cooperatively as a system-in-a-package. In one example, an electrically conductive element having at least a portion having a thickness less than 10 microns, may be formed by plating, and may electrically connect two or more of the first, second or third elements. The conductive element may entirely underlie a surface of another one of the substantially planar elements. | 03-19-2015 |
20150084188 | STACKABLE MOLDED MICROELECTRONIC PACKAGES - A microelectronic package has a microelectronic element and conductive posts or masses projecting above a surface of the substrate. Conductive elements at a surface of the substrate opposite therefrom are electrically interconnected with the microelectronic element. An encapsulant overlies at least a portion of the microelectronic element and may be in contact with the conductive posts or masses. The encapsulant may have openings permitting electrical connections with the conductive posts or masses. The openings may partially expose conductive masses joined to posts, fully expose top surfaces of posts and partially expose edge surfaces of posts, or may partially expose top surfaces of posts. | 03-26-2015 |
20150087146 | MICROELECTRONIC INTERCONNECT ELEMENT WITH DECREASED CONDUCTOR SPACING - A microelectronic interconnect element can include a plurality of first metal lines and a plurality of second metal lines interleaved with the first metal lines. Each of the first and second metal lines has a surface extending within the same reference plane. The first metal lines have surfaces above the reference plane and remote therefrom and the second metal lines have surfaces below the reference plane and remote therefrom. A dielectric layer can separate a metal line of the first metal lines from an adjacent metal line of the second metal lines. | 03-26-2015 |