Patent application number | Description | Published |
20120025389 | Hermetic Wafer Level Packaging - Provided is a wafer level packaging. The packaging includes a first semiconductor wafer having a transistor device and a first bonding layer that includes a first material. The packaging includes a second semiconductor wafer having a second bonding layer that includes a second material different from the first material, one of the first and second materials being aluminum-based, and the other thereof being titanium-based. Wherein a portion of the second wafer is diffusively bonded to the first wafer through the first and second bonding layers. | 02-02-2012 |
20120043626 | MICROSTRUCTURE DEVICE WITH AN IMPROVED ANCHOR - The present disclosure provides a system of fabricating a microstructure device with an improved anchor. A method of fabricating a microstructure device with an improved anchor includes providing a substrate and forming an oxide layer on the substrate. Then, a cavity is etched in the oxide layer, such that the cavity includes a sidewall in the oxide layer. A microstructure device layer is then bonded to the oxide layer over the cavity. Forming a microstructure device, a trench is etched in the device layer to define an outer boundary of the microstructure device. In an embodiment, the outer boundary is substantially outside of the sidewall of the cavity. Then, the sidewall of the cavity is etched away through the trench in the device layer, to thereby suspend the microstructure device over the cavity. | 02-23-2012 |
20120061776 | WAFER LEVEL PACKAGING - A method of wafer level packaging includes providing a substrate including a buried oxide layer and a top oxide layer, and etching the substrate to form openings above the buried oxide layer and a micro-electro-mechanical systems (MEMS) resonator element between the openings, the MEMS resonator element enclosed within the buried oxide layer, the top oxide layer, and sidewall oxide layers. The method further includes filling the openings with polysilicon to form polysilicon electrodes adjacent the MEMS resonator element, removing the top oxide layer and the sidewall oxide layers adjacent the MEMS resonator element, bonding the polysilicon electrodes to one of a complementary metal-oxide semiconductor (CMOS) wafer or a carrier wafer, removing the buried oxide layer adjacent the MEMS resonator element, and bonding the substrate to a capping wafer to seal the MEMS resonator element between the capping wafer and one of the CMOS wafer or the carrier wafer. | 03-15-2012 |
20120068276 | MICROSTRUCTURE WITH AN ENHANCED ANCHOR - The present disclosure provides a microstructure device with an enhanced anchor and a narrow air gap. One embodiment of a microstructure device provided herein includes a layered wafer. The layered wafer includes a silicon handle layer, a buried oxide layer formed on the handle layer, and a silicon device layer formed on the buried oxide layer. A top oxide layer is formed on the device layer. The top oxide layer, the device layer, and the buried oxide layer are etched, thereby forming trenches to create an anchor and a microstructure device in the device layer. In process of fabricating the device, a thermal oxide layer is formed along sides of the microstructure device to enclose the microstructure device in the buried oxide layer, the top oxide layer and the thermal oxide layer. Then, a poly layer if formed to fill in the trenches and enclose the anchor. After the poly layer fills in the trenches, the oxide layers enclosing the microstructure device are etched away, releasing the microstructure device. | 03-22-2012 |
20120074590 | MULTIPLE BONDING IN WAFER LEVEL PACKAGING - The present disclosure provides a method for fabricating a MEMS device including multiple bonding of substrates. In an embodiment, a method includes providing a micro-electro-mechanical systems (MEMS) substrate including a first bonding layer, providing a semiconductor substrate including a second bonding layer, and providing a cap including a third bonding layer. The method further includes bonding the MEMS substrate to the semiconductor substrate at the first and second bonding layers, and bonding the cap to the semiconductor substrate at the second and third bonding layers to hermetically seal the MEMS substrate between the cap and the semiconductor substrate. A MEMS device fabricated by the above method is also provided. | 03-29-2012 |
20120098074 | MEMS DEVICE WITH RELEASE APERTURE - The present disclosure provides a method of fabricating a micro-electro-mechanical systems (MEMS) device. In an embodiment, a method includes providing a substrate including a first sacrificial layer, forming a micro-electro-mechanical systems (MEMS) structure above the first sacrificial layer, and forming a release aperture at substantially a same level above the first sacrificial layer as the MEMS structure. The method further includes forming a second sacrificial layer above the MEMS structure and within the release aperture, and forming a first cap over the second sacrificial layer and the MEMS structure, wherein a leg of the first cap is disposed between the MEMS structure and the release aperture. The method further includes removing the first sacrificial layer, removing the second sacrificial layer through the release aperture, and plugging the release aperture. A MEMS device formed by such a method is also provided. | 04-26-2012 |
20120125747 | MEMS SWITCH WITH REDUCED DIELECTRIC CHARGING EFFECT - The present disclosure provides in one embodiment, a semiconductor device that includes a MEMS switch having a substrate, a first dielectric layer disposed above the substrate, and a bottom signal electrode, a bump, and a bottom actuation electrode disposed above the first dielectric layer. The MEMS switch further includes a second dielectric layer enclosing the bottom signal electrode, and a movable member including a top signal electrode disposed above the bottom signal electrode and a top actuation electrode disposed above the bottom actuation electrode and the bump, wherein the top actuation electrode is electrically coupled to the bump. A method of fabricating a MEMS switch is also disclosed. | 05-24-2012 |
20120161582 | MEMS KINETIC ENERGY CONVERSION - The present disclosure provides a micro device. The device has a micro-electro-mechanical systems (MEMS) movable structure, a plurality of metal loops over the MEMS movable structure, and a piezoelectric element over the MEMS movable structure. Frontside and backside capping wafers are bonded to the MEMS structure, with the frontside and backside capping wafers encapsulating the MEMS movable structure, the plurality of metal loops, and the piezoelectric element. The device further includes a magnet disposed on the frontside capping wafer over the plurality of metal loops. | 06-28-2012 |
20120181637 | BULK SILICON MOVING MEMBER WITH DIMPLE - A method for forming a semiconductor device includes forming a substrate, forming a moveable member of bulk silicon and forming a first dimple structure on a first surface of the moveable member, where the first surface faces the substrate. | 07-19-2012 |
20120187983 | FREQUENCY GENERATOR - A mechanical frequency generator has a first mechanical resonator and a second mechanical resonator and a circuit connected with the first and second mechanical resonators. The first and second mechanical resonators having substantially the same resonator frequency coefficients as a function of an environment of the first and the second mechanical resonators. The first mechanical resonator differing in size from the second mechanical resonator. The circuit adapted to generate a difference frequency signal responsive to the first and second mechanical resonator frequency signals and based on the first and the second predetermined resonant frequencies. | 07-26-2012 |
20120261830 | MEMS DEVICE ETCH STOP - The present disclosure provides a micro-electro-mechanical systems (MEMS) device and a method for fabricating such a device. In an embodiment, a MEMS device includes a substrate, a dielectric layer above the substrate, an etch stop layer above the dielectric layer, and two anchor plugs above the dielectric layer, the two anchor plugs each contacting the etch stop layer or a top metal layer disposed above the dielectric layer. The device further comprises a MEMS structure layer disposed above a cavity formed between the two anchor plugs and above the etch stop layer from release of a sacrificial layer. | 10-18-2012 |
20120309197 | METHODS OF FORMING SEMICONDUCTOR STRUCTURES - A method of forming a semiconductor structure includes forming an opening in a substrate. A dielectric layer is formed and substantially conformal to the opening. A sacrificial structure is formed within the opening, covering a portion of the dielectric layer. A portion of the dielectric layer is removed by using the sacrificial structure as an etch mask layer. The sacrificial structure is removed. | 12-06-2012 |
20120313235 | Semiconductor Devices With Moving Members and Methods for Making the Same - The present disclosure provides an embodiment of a micro-electro-mechanical system (MEMS) structure, the MEMS structure comprising a MEMS substrate; a first and second conductive plugs of a semiconductor material disposed on the MEMS substrate, wherein the first conductive plug is configured for electrical interconnection and the second conductive plug is configured as an anti-stiction bump; a MEMS device configured on the MEMS substrate and electrically coupled with the first conductive plug; and a cap substrate bonded to the MEMS substrate such that the MEMS device is enclosed therebetween. | 12-13-2012 |
20130015743 | MEMS Structure And Method Of Forming Same - A microelectromechanical system (MEMS) device that reduces or eliminates stiction includes a substrate and a movable element at least partially suspended above the substrate and having at least one degree of freedom. A protrusion extends from the substrate and is configured to contact the movable element when the moving element moves in the at least one degree of freedom. The protrusion comprises a surface having a low surface energy relative a silicon oxide surface. The protrusion may be coupled to a voltage potential node to avoid or counteract electrostatic forces. | 01-17-2013 |
20130043547 | MEMS DEVICE HAVING CHIP SCALE PACKAGING - A method and device having chip scale MEMS packaging is described. A first substrate includes a MEMS device and a second substrate includes an integrated circuit. The frontside of the first substrate is bonded to the backside of the second substrate. Thus, the second substrate provides a cavity to encase, protect or operate the MEMS device within. The bond may provide an electrical connection between the first and second substrate. In an embodiment, a through silicon via is used to carry the signals from the first substrate to an I/O connection on the frontside of the second substrate. | 02-21-2013 |
20130075834 | Bulk Silicon Moving Member with Dimple - A method for forming a semiconductor device includes forming a substrate, forming a moveable member of bulk silicon and forming a first dimple structure on a first surface of the moveable member, where the first surface faces the substrate. | 03-28-2013 |
20130102101 | Wafer Level Packaging - A method of wafer level packaging includes providing a substrate including a buried oxide layer and a top oxide layer, and etching the substrate to form openings above the buried oxide layer and a micro-electro-mechanical systems (MEMS) resonator element between the openings, the MEMS resonator element enclosed within the buried oxide layer, the top oxide layer, and sidewall oxide layers. The method further includes filling the openings with polysilicon to form polysilicon electrodes adjacent the MEMS resonator element, removing the top oxide layer and the sidewall oxide layers adjacent the MEMS resonator element, bonding the polysilicon electrodes to one of a complementary metal-oxide semiconductor (CMOS) wafer or a carrier wafer, removing the buried oxide layer adjacent the MEMS resonator element, and bonding the substrate to a capping wafer to seal the MEMS resonator element between the capping wafer and one of the CMOS wafer or the carrier wafer. | 04-25-2013 |
20130105868 | CMOS COMPATIBLE BIOFET | 05-02-2013 |
20130126989 | Microstructure Device with an Improved Anchor - A microelectromechanical system (MEMS) device includes a substrate and an oxide layer formed on the substrate. A cavity is etched in the oxide layer. A microstructure device layer is bonded to the oxide layer, over the cavity. The microstructure device layer includes a substantially solid microstructure MEMS device formed in the microstructure device layer and suspended over a portion of the cavity. An anchor is formed in the device layer and configured to support the microstructure device, the anchor having an undercut in the oxide layer. The undercut has a length along the anchor that is less than one-half a length of an outer boundary dimension of the microstructure MEMS device. | 05-23-2013 |
20130140653 | MEMS DEVICE ETCH STOP - The present disclosure provides a micro-electro-mechanical systems (MEMS) device and a method for fabricating such a device. In an embodiment, a MEMS device includes a substrate, a dielectric layer above the substrate, an etch stop layer above the dielectric layer, and two anchor plugs above the dielectric layer, the two anchor plugs each contacting the etch stop layer or a top metal layer disposed above the dielectric layer. The device further comprises a MEMS structure layer disposed above a cavity formed between the two anchor plugs and above the etch stop layer from release of a sacrificial layer. | 06-06-2013 |
20130147317 | MEMS KINETIC ENERGY CONVERSION - The present disclosure provides a micro device. The device has a micro-electro-mechanical systems (MEMS) movable structure, a plurality of metal loops over the MEMS movable structure, a piezoelectric element over the MEMS movable structure, and a magnet disposed over the plurality of metal loops. The MEMS movable structure, the plurality of metal loops, and the piezoelectric element are encapsulated. | 06-13-2013 |
20130168852 | MEMS Devices and Methods of Forming Same - A microelectromechanical system (MEMS) device may include a MEMS structure over a first substrate. The MEMS structure comprises a movable element. Depositing a first conductive material over the first substrate and etching trenches in a second substrate. Filling the trenches with a second conductive material and depositing a third conductive material over the second conductive material and the second substrate. Bonding the first substrate and the second substrate and thinning a backside of the second substrate which exposes the second conductive material in the trenches. | 07-04-2013 |
20130193527 | MICRO-ELECTRO MECHANICAL SYSTEM (MEMS) STRUCTURES WITH THROUGH SUBSTRATE VIAS AND METHODS OF FORMING THE SAME - The present disclosure includes micro-electro mechanical system (MEMS) structures and methods of forming the same. Substrates of the MEMS structures are bonded together by fusion bonding at high processing temperatures, which enables more complete removal of chemical species from the dielectric materials in the substrates prior to sealing cavities of the MEMS structures. Fusion bonding of MEMS structures reduces outgassing of chemical species and is compatible with the cavity formation process. The MEMS structures bonded by fusion bonding are mechanically stronger compared to eutectic bonding due to a higher bonding ratio. In addition, fusion bonding enables the formation of through substrate vias (TSVs) in the MEMS structures. | 08-01-2013 |
20130264610 | TEMPERATURE STABILITIZED MEMS - A semiconductor device with temperature control system. Embodiments of the device may include a MEMS chip including a first heater with a dedicated first temperature control loop and a CMOS chip including a second heater with a dedicated second temperature control loop. Each control loop may have a dedicated temperature sensor for controlling the thermal output of each heater. The first heater and sensor are disposed proximate to a MEMS device in the MEMS chip for direct heating thereof. The temperature of the MEMS chip and CMOS chip are independently controllable of each other via the temperature control loops. | 10-10-2013 |
20130285170 | MULTIPLE BONDING IN WAFER LEVEL PACKAGING - A MEMS device is described. The device includes a micro-electro-mechanical systems (MEMS) substrate including a first bonding layer, a semiconductor substrate including a second bonding layer, and a cap including a third bonding layer, the cap coupled to the semiconductor substrate by bonding the second bonding layer to the third bonding layer. The first bonding layer includes silicon, the semiconductor substrate is electrically coupled to the MEMS substrate by bonding the first bonding layer to the second bonding layer, and the MEMS substrate is hermetically sealed between the cap and the semiconductor substrate. | 10-31-2013 |
20130334620 | MEMS Devices and Fabrication Methods Thereof - A method for fabricating a MEMS device includes providing a micro-electro-mechanical system (MEMS) substrate having a sacrificial layer on a first side, providing a carrier including a plurality of cavities, bonding the first side of the MEMS substrate on the carrier, forming a first bonding material layer on a second side of the MEMS substrate, applying a sacrificial layer removal process to the MEMS substrate, providing a semiconductor substrate including a second bonding material layer and bonding the semiconductor substrate on the second side of the MEMS substrate. | 12-19-2013 |
20140035158 | Integrated Semiconductor Device and Wafer Level Method of Fabricating the Same - The present disclosure provides one embodiment of a stacked semiconductor device. The stacked semiconductor device includes a first substrate; a first bond pad over the first substrate; a second substrate including a second electrical device fabricated thereon; a second bond pad over the second electrical device over the second substrate, the second bond pad electrically connecting to the second electrical device; a second insulation layer over the second bond pad having a top surface, the second insulation layer being bonded toward the first bond pad of the first substrate; and a through-substrate-via (“TSV”) extending from a surface opposite to the first bond pad through the first substrate and through the top surface of the second insulation layer to the second bond pad. | 02-06-2014 |
20140042562 | MEMS Devices and Methods for Forming the Same - A device includes a Micro-Electro-Mechanical System (MEMS) wafer having a MEMS device therein. The MEMS device includes a movable element, and first openings in the MEMS wafer. The movable element is disposed in the first openings. A carrier wafer is bonded to the MEMS wafer. The carrier wafer includes a second opening connected to the first openings, wherein the second opening includes an entry portion extending from a surface of the carrier wafer into the carrier wafer, and an inner portion wider than the entry portion, wherein the inner portion is deeper in the carrier wafer than the entry portion. | 02-13-2014 |
20140054461 | LIGHT DETECTOR WITH GE FILM - A light detector includes a first light sensor and a second light sensor to detect incident light. A Ge film is disposed over the first light sensor to pass infra-red (IR) wavelength light and to block visible wavelength light. The Ge film does not cover the second light sensor. | 02-27-2014 |
20140103461 | MEMS Devices and Fabrication Methods Thereof - A method for fabricating a MEMS device includes providing a micro-electro-mechanical system (MEMS) substrate having a sacrificial layer on a first side, providing a carrier including a plurality of cavities, bonding the first side of the MEMS substrate on the carrier, forming a first bonding material layer on a second side of the MEMS substrate, applying a sacrificial layer removal process to the MEMS substrate, providing a semiconductor substrate including a second bonding material layer and bonding the semiconductor substrate on the second side of the MEMS substrate. | 04-17-2014 |
20140151821 | MEMS STRUCTURE WITH ADAPTABLE INTER-SUBSTRATE BOND - A MEMS structure incorporating multiple joined substrates and a method for forming the MEMS structure are disclosed. An exemplary MEMS structure includes a first substrate having a bottom surface and a second substrate having a top surface substantially parallel to the bottom surface of the first substrate. The bottom surface of the first substrate is connected to the top surface of the second substrate by an anchor, such that the anchor does not extend through either the bottom surface of the first substrate or the top surface of the second substrate. The MEMS structure may include a bonding layer in contact with the bottom surface of the first substrate, and shaped to at least partially envelop the anchor. | 06-05-2014 |
20140154841 | Hermetic Wafer Level Packaging - Provided is a wafer level packaging. The packaging includes a first semiconductor wafer having a transistor device and a first bonding layer that includes a first material. The packaging includes a second semiconductor wafer having a second bonding layer that includes a second material different from the first material, one of the first and second materials being aluminum-based, and the other thereof being titanium-based. Wherein a portion of the second wafer is diffusively bonded to the first wafer through the first and second bonding layers. | 06-05-2014 |
20140183611 | METHOD TO INTEGRATE DIFFERENT FUNCTION DEVICES FABRICATED BY DIFFERENT PROCESS TECHNOLOGIES - The present disclosure is directed to an apparatus and method for manufacture thereof. The apparatus includes a first passive substrate bonded to a second active substrate by a conductive metal interface. The conductive metal interface allows for integration of different function devices at a wafer level. | 07-03-2014 |
20140206123 | Dual Layer Microelectromechanical Systems Device and Method of Manufacturing Same - Exemplary microelectromechanical system (MEMS) devices, and methods for fabricating such are disclosed. An exemplary method includes providing a silicon-on-insulator (SOI) substrate, wherein the SOI substrate includes a first silicon layer separated from a second silicon layer by an insulator layer; processing the first silicon layer to form a first structure layer of a MEMS device; bonding the first structure layer to a substrate; and processing the second silicon layer to form a second structure layer of the MEMS device. | 07-24-2014 |
20140252358 | Methods and Apparatus for MEMS Devices with Increased Sensitivity - Methods and apparatus for forming MEMS devices. An apparatus includes at least a portion of a semiconductor substrate having a first thickness and patterned to form a moveable mass; a moving sense electrode forming the first plate of a first capacitance; at least one anchor patterned from the semiconductor substrate and having a portion that forms the second plate of the first capacitance and spaced by a first gap from the first plate; a layer of semiconductor material of a second thickness patterned to form a first electrode forming a first plate of a second capacitance and further patterned to form a second electrode overlying the at least one anchor and forming a second plate spaced by a second gap that is less than the first gap; wherein a total capacitance is formed that is the sum of the first capacitance and the second capacitance. Methods are disclosed. | 09-11-2014 |
20140264474 | STACKED SEMICONDUCTOR DEVICE AND METHOD OF FORMING THE SAME RELATED CASES - A stacked semiconductor device includes a CMOS device and a MEMS device. The CMOS device includes a multilayer interconnect with metal elements disposed over the multilayer interconnect. The MEMS device includes metal sections with a first dielectric layer disposed over the metal sections. A cavity in the first dielectric layer exposes portions of the metal sections. A dielectric stop layer is disposed at least over the interior surface of the cavity. A movable structure is disposed over a front surface of the first dielectric layer and suspending over the cavity. The movable structure includes a second dielectric layer over the front surface of the first dielectric layer and suspending over the cavity, metal features over the second dielectric layer, and a flexible dielectric membrane over the metal features. The CMOS device is bonded to the MEMS device with the metal elements toward the flexible dielectric membrane. | 09-18-2014 |
20140264648 | MEMS Integrated Pressure Sensor Devices and Methods of Forming Same - A method embodiment includes providing a micro-electromechanical (MEMS) wafer including a polysilicon layer having a first and a second portion. A carrier wafer is bonded to a first surface of the MEMS wafer. Bonding the carrier wafer creates a first cavity. A first surface of the first portion of the polysilicon layer is exposed to a pressure level of the first cavity. A cap wafer is bonded to a second surface of the MEMS wafer opposite the first surface of the MEMS wafer. The bonding the cap wafer creates a second cavity comprising the second portion of the polysilicon layer and a third cavity. A second surface of the first portion of the polysilicon layer is exposed to a pressure level of the third cavity. The first cavity or the third cavity is exposed to an ambient environment. | 09-18-2014 |
20140264653 | MEMS Pressure Sensor and Microphone Devices Having Through-Vias and Methods of Forming Same - A method embodiment includes providing a MEMS wafer. A portion of the MEMS wafer is patterned to provide a first membrane for a microphone device and a second membrane for a pressure sensor device. A carrier wafer is bonded to the MEMS wafer. The carrier wafer is etched to expose the first membrane and a first surface of the second membrane to an ambient environment. A MEMS structure is formed in the MEMS wafer. A cap wafer is bonded to a side of the MEMS wafer opposing the carrier wafer to form a first sealed cavity including the MEMS structure and a second sealed cavity including a second surface of the second membrane for the pressure sensor device. The cap wafer comprises an interconnect structure. A through-via electrically connected to the interconnect structure is formed in the cap wafer. | 09-18-2014 |
20140264661 | MEMS Devices and Methods for Forming Same - Embodiments of the present disclosure include MEMS devices and methods for forming MEMS devices. An embodiment is a method for forming a microelectromechanical system (MEMS) device, the method including forming a MEMS wafer having a first cavity, the first cavity having a first pressure, and bonding a carrier wafer to a first side of the MEMS wafer, the bonding forming a second cavity, the second cavity having a second pressure, the second pressure being greater than the first pressure. The method further includes bonding a cap wafer to a second side of the MEMS wafer, the second side being opposite the first side, the bonding forming a third cavity, the third cavity having a third pressure, the third pressure being greater than the first pressure and less than the second pressure. | 09-18-2014 |
20140264662 | MEMS Integrated Pressure Sensor and Microphone Devices and Methods of Forming Same - A method embodiment for forming a micro-electromechanical (MEMS) device includes providing a MEMS wafer, wherein a portion of the MEMS wafer is patterned to provide a first membrane for a microphone device and a second membrane for a pressure sensor device. A carrier wafer is bonded to the MEMS wafer, and the carrier wafer is etched to expose the first membrane for the microphone device to an ambient environment. A MEMS substrate is patterned and portions of a first sacrificial layer are removed of the MEMS wafer to form a MEMS structure. A cap wafer is bonded to a side of the MEMS wafer opposing the carrier wafer to form a first sealed cavity including the MEMS structure. A second sealed cavity and a cavity exposed to an ambient environment on opposing sides of the second membrane for the pressure sensor device are formed. | 09-18-2014 |
20140264744 | STACKED SEMICONDUCTOR DEVICE AND METHOD OF FORMING THE SAME - A stacked semiconductor device includes a first substrate. A multilayer interconnect is disposed over the first substrate. Metal sections are disposed over the multilayer interconnect. First bonding features are over the metal sections. A second substrate has a front surface. A cavity extends from the front surface into a depth D in the second substrate. The cavity has an interior surface. A stop layer is disposed over the interior surface of the cavity. A movable structure is disposed over the front surface of the second substrate and suspending over the cavity. The movable structure includes a dielectric membrane, metal units over the dielectric membrane and a cap dielectric layer over the metal units. Second bonding features are over the cap dielectric layer and bonded to the first bonding features. The second bonding features extend through the cap dielectric layer and electrically coupled to the metal units. | 09-18-2014 |
20140270272 | Structure and Method for Integrated Microphone - The present disclosure provides one embodiment of an integrated microphone structure. The integrated microphone structure includes a first silicon substrate patterned as a first plate; a silicon oxide layer formed on one side of the first silicon substrate; a second silicon substrate bonded to the first substrate through the silicon oxide layer such that the silicon oxide layer is sandwiched between the first and second silicon substrates; and a diaphragm secured on the silicon oxide layer and disposed between the first and second silicon substrates, wherein the first plate and the diaphragm are configured to form a capacitive microphone. | 09-18-2014 |
20140273281 | METHOD FOR FORMING BIOCHIPS AND BIOCHIPS WITH NON-ORGANIC LANDINGS FOR IMPROVED THERMAL BUDGET - The present disclosure provides biochips and methods of fabricating biochips. The method includes combining three portions: a transparent substrate, a first substrate with microfluidic channels therein, and a second substrate. Through-holes for inlet and outlet are formed in the transparent substrate or the second substrate. Various non-organic landings with support medium for bio-materials to attach are formed on the first substrate and the second substrate before they are combined. In other embodiments, the microfluidic channel is formed of an adhesion layer between a transparent substrate and a second substrate with landings on the substrates. | 09-18-2014 |
20140319631 | MEMS Integrated Pressure Sensor Devices having Isotropic Cavities and Methods of Forming Same - A method embodiment includes providing a MEMS wafer comprising an oxide layer, a MEMS substrate, a polysilicon layer. A carrier wafer comprising a first cavity formed using isotropic etching is bonded to the MEMS, wherein the first cavity is aligned with an exposed first portion of the polysilicon layer. The MEMS substrate is patterned, and portions of the sacrificial oxide layer are removed to form a first and second MEMS structure. A cap wafer including a second cavity is bonded to the MEMS wafer, wherein the bonding creates a first sealed cavity including the second cavity aligned to the first MEMS structure, and wherein the second MEMS structure is disposed between a second portion of the polysilicon layer and the cap wafer. Portions of the carrier wafer are removed so that first cavity acts as a channel to ambient pressure for the first MEMS structure. | 10-30-2014 |
20140353776 | MEMS Structure with Adaptable Inter-Substrate Bond - A MEMS structure incorporating multiple joined substrates and a method for forming the MEMS structure are disclosed. An exemplary MEMS structure includes a first substrate having a bottom surface and a second substrate having a top surface substantially parallel to the bottom surface of the first substrate. The bottom surface of the first substrate is connected to the top surface of the second substrate by an anchor, such that the anchor does not extend through either the bottom surface of the first substrate or the top surface of the second substrate. The MEMS structure may include a bonding layer in contact with the bottom surface of the first substrate, and shaped to at least partially envelop the anchor. | 12-04-2014 |
20150060954 | CMOS-MEMS Integrated Flow for Making a Pressure Sensitive Transducer - A sensor is made up of two substrates which are adhered together. A first substrate includes a pressure-sensitive micro-electrical-mechanical (MEMS) structure and a conductive contact structure that protrudes outwardly beyond a first face of the first substrate. A second substrate includes a complementary metal oxide semiconductor (CMOS) device and a receiving structure made up of sidewalls that meet a conductive surface which is recessed from a first face of the second substrate. A conductive bonding material physically adheres the conductive contact structure to the conductive surface and electrically couples the MEMS structure to the CMOS device. | 03-05-2015 |
20150061046 | WAFER LEVEL METHOD OF SEALING DIFFERENT PRESSURE LEVELS FOR MEMS SENSORS - The present disclosure relates to a method of forming a plurality of MEMs device having a plurality of chambers with different pressures on a substrate, and an associated apparatus. In some embodiments, the method is performed by providing a device wafer having a plurality of microelectromechanical system (MEMs) devices. A cap wafer is bonded onto the device wafer in a first ambient environment having a first pressure. The bonding forms a plurality of chambers abutting the plurality of MEMs devices, which are held at the first pressure. One or more openings are formed in one or more of the plurality of chambers. The one or more openings in the one or more of the plurality of chambers are then sealed in a different ambient environment having a different pressure, thereby causing the one or more of the plurality of chambers to be held at the different pressure. | 03-05-2015 |
20150076710 | INTEGRATED SEMICONDUCTOR DEVICE AND WAFER LEVEL METHOD OF FABRICATING THE SAME - The present disclosure provides one embodiment of a stacked semiconductor device. The stacked semiconductor device includes a first substrate; a first bond pad over the first substrate; a second substrate including a second electrical device fabricated thereon; a second bond pad over the second electrical device over the second substrate, the second bond pad electrically connecting to the second electrical device; a second insulation layer over the second bond pad having a top surface, the second insulation layer being bonded toward the first bond pad of the first substrate; and a through-substrate-via (“TSV”) extending from a surface opposite to the first bond pad through the first substrate and through the top surface of the second insulation layer to the second bond pad. | 03-19-2015 |