Patent application number | Description | Published |
20080197495 | STRUCTURE FOR REDUCING LATERAL FRINGE CAPACITANCE IN SEMICONDUCTOR DEVICES - A semiconductor structure includes a plurality of conductive lines formed within an interlevel dielectric (ILD) layer and a non-planar cap layer formed over the ILD layer and the conductive lines, wherein the cap layer is raised with respect to the conductive lines at locations between the conductive lines. | 08-21-2008 |
20080254612 | POLYCARBOSILANE BURIED ETCH STOPS IN INTERCONNECT STRUCTURES - Interconnect structures having buried etch stop layers with low dielectric constants and methods relating to the generation of such buried etch stop layers are described herein. The inventive interconnect structure comprises a buried etch stop layer comprised of a polymeric material having a composition Si | 10-16-2008 |
20080286909 | SIDEWALL SEMICONDUCTOR TRANSISTORS - A novel transistor structure and method for fabricating the same. First, a substrate, a semiconductor region, a gate dielectric region, and a gate block are provided. The semiconductor region, the gate dielectric region, and the gate block are on the substrate. The gate dielectric region is sandwiched between the semiconductor region and the gate block. The semiconductor region is electrically insulated from the gate block by the gate dielectric region. The semiconductor region and the gate dielectric region share an interface surface which is essentially perpendicular to a top surface of the substrate. The semiconductor region and the gate dielectric region do not share any interface surface that is essentially parallel to a top surface of the substrate. Next, a gate region is formed from the gate block. Then, first and second source/drain regions are formed in the semiconductor region. | 11-20-2008 |
20090001592 | METAL INTERCONNECT FORMING METHODS AND IC CHIP INCLUDING METAL INTERCONNECT - Methods of forming a metal interconnect and an IC chip including the metal interconnect are disclosed. One embodiment of the method may include providing an integrated circuit (IC) chip up to and including a middle of line (MOL) layer, the MOL layer including a contact positioned within a first dielectric; recessing the first dielectric such that the contact extends beyond an upper surface of the first dielectric; forming a second dielectric over the first dielectric such that the second dielectric surrounds at least a portion of the contact, the second dielectric having a lower dielectric constant than the first dielectric; forming a planarizing layer over the second dielectric; forming an opening through the planarizing layer and into the second dielectric to the contact; and forming a metal in the opening to form the metal interconnect. | 01-01-2009 |
20090014868 | MANUFACTURING IC CHIP IN PORTIONS FOR LATER COMBINING, AND RELATED STRUCTURE - Methods of manufacturing an IC chip in portions for later combining and a related structure are disclosed. In one embodiment, the method includes: fabricating a first portion of the IC chip, the first portion including a structure from a selected level of back-end-of-line (BEOL) processing up to an end of the BEOL processing, the first portion providing a specific functionality when combined with a second portion of the IC chip, fabricating the second portion of the IC chip, the second portion including a structure from a device level of the IC chip up to the selected level of the BEOL processing, the second portion having structure providing generic IC chip functionality. The fabrication of the portions may occur at a single location or different locations, and the combining may occur at the same location or different location as one or more of the fabrication processes. | 01-15-2009 |
20090017616 | METHOD FOR FORMING CONDUCTIVE STRUCTURES - A method of forming a method a conductive wire. The method includes forming a dielectric hardmask layer on a dielectric layer; forming an electrically conductive hardmask layer on the dielectric hardmask layer; forming a trench extending through the conductive and dielectric hardmask layers into the dielectric layer; depositing a liner/seed layer on the conductive hardmask layer and the sidewalls and bottom of the trench; filling the trench with a fill material; removing the liner/seed layer from the top surface of the conductive hardmask layer; removing the fill material from the trench; electroplating a metal layer onto exposed surfaces of the conductive hardmask layer and liner/seed layer; and removing the metal layer and the conductive hardmask layer from the dielectric hardmask layer so the metal layer and edges of the liner/seed layer are coplanar with the top surface of the dielectric hardmask layer. | 01-15-2009 |
20090085210 | STRUCTURES AND METHODS FOR REDUCTION OF PARASITIC CAPACITANCES IN SEMICONDUCTOR INTEGRATED CIRCUITS - A semiconductor structure and a method for forming the same. The structure includes (a) a substrate which includes semiconductor devices and (b) a first ILD (inter-level dielectric) layer on top of the substrate. The structure further includes N first actual metal lines in the first ILD layer, N being a positive integer. The N first actual metal lines are electrically connected to the semiconductor devices. The structure further includes first trenches in the first ILD layer. The first trenches are not completely filled with solid materials. If the first trenches are completely filled with first dummy metal lines, then (i) the first dummy metal lines are not electrically connected to any semiconductor device and (ii) the N first actual metal lines and the first dummy metal lines provide an essentially uniform pattern density of metal lines across the first ILD layer. | 04-02-2009 |
20090087992 | METHOD OF MINIMIZING VIA SIDEWALL DAMAGES DURING DUAL DAMASCENE TRENCH REACTIVE ION ETCHING IN A VIA FIRST SCHEME - A method of minimizing undercut of a hard mask in an integrated circuit (IC) structure including steps of providing an IC structure having a substrate, a interlayer dielectric layer, and a hard mask, forming a via in said IC structure, and depositing an organic planarizing layer (OPL) over the IC structure such that it fills the vias formed therein. The method also includes steps of forming a masking structure layer over the OPL, forming an opening in the masking structure that has a critical dimension (CD) smaller than an opening design dimension, anisotropic etching the OPL such that sidewall of the via remains covered with the OPL while forming a trench, and removing any remaining OPL on the sidewalls and trench, wherein the undercut of the sidewalls with respect to the hard mask is minimized by the covering of OPL during the anisotropic etching process. | 04-02-2009 |
20090096056 | ON-CHIP COOLING SYSTEMS FOR INTEGRATED CIRCUITS - Structures and methods for forming the same. A semiconductor chip includes a substrate and a transistor. The chip includes N interconnect layers on the substrate, N being a positive integer. The chip includes a cooling pipes system inside the N interconnect layers. The cooling pipes system does not include any solid or liquid material. Given any first point and any second point in the cooling pipes system, there exists a continuous path which connects the first and second points and which is totally within the cooling pipes system. A first portion of the cooling pipes system overlaps the transistor. A second portion of the cooling pipes system is higher than the substrate and lower than a top interconnect layer. The second portion is in direct physical contact with a surrounding ambient. | 04-16-2009 |
20090107956 | Thermal Gradient Control of High Aspect Ratio Etching and Deposition Processes - A technique is described whereby temperature gradients are created within a semiconductor wafer. Temperature sensitive etching and/or deposition processes are then employed. These temperature sensitive processes proceed at different rates in regions with different temperatures. To reduce pinch off in etching processes, a temperature sensitive etch process is selected and a temperature gradient is created between the surface and subsurface of a wafer such that the etching process proceeds more slowly at the surface than deeper in the wafer. This reduces “crusting” of solid reaction products at trench openings, thereby eliminating pinch off in many cases. Similar temperature-sensitive deposition processes can be employed to produce void-free high aspect ratio conductors and trench fills. | 04-30-2009 |
20090117360 | SELF-ASSEMBLED MATERIAL PATTERN TRANSFER CONTRAST ENHANCEMENT - A non-photosensitive polymeric resist containing at least two immiscible polymeric block components is deposited on the planar surface. The non-photosensitive polymeric resist is annealed to allow phase separation of immiscible components and developed to remove at least one of the at least two polymeric block components. Nanoscale features, i.e., features of nanometer scale, including at least one recessed region having a nanoscale dimension is formed in the polymeric resist. The top surface of the polymeric resist is modified for enhanced etch resistance by an exposure to an energetic beam, which allows the top surface of the patterned polymeric resist to become more resistant to etching processes and chemistries. The enhanced ratio of etch resistance between the two types of surfaces provides improved image contrast and fidelity between areas having the top surface and the at least one recessed region. | 05-07-2009 |
20090142894 | METHOD FOR FABRICATING A SEMICONDUCTOR STRUCTURE - A method for fabricating a semiconductor structure. The novel transistor structure comprises first and second source/drain (S/D) regions whose top surfaces are lower than a top surface of the channel region of the transistor structure. A semiconductor layer and a gate stack on the semiconductor layer are provided. The semiconductor layer includes (i) a channel region directly beneath the gate stack, and (ii) first and second semiconductor regions essentially not covered by the gate stack, and wherein the channel region is disposed between the first and second semiconductor regions. The first and second semiconductor regions are removed. Regions directly beneath the removed first and second semiconductor regions are removed so as to form first and second source/drain regions, respectively, such that top surfaces of the first and second source/drain regions are below a top surface of the channel region. | 06-04-2009 |
20100133694 | METAL INTERCONNECT AND IC CHIP INCLUDING METAL INTERCONNECT - A metal interconnect and an IC chip including the metal interconnect are disclosed. One embodiment of the method may include providing an integrated circuit (IC) chip up to and including a middle of line (MOL) layer, the MOL layer including a contact positioned within a first dielectric; recessing the first dielectric such that the contact extends beyond an upper surface of the first dielectric; forming a second dielectric over the first dielectric such that the second dielectric surrounds at least a portion of the contact, the second dielectric having a lower dielectric constant than the first dielectric; forming a planarizing layer over the second dielectric; forming an opening through the planarizing layer and into the second dielectric to the contact; and forming a metal in the opening to form the metal interconnect. | 06-03-2010 |
20100136800 | ON-CHIP COOLING SYSTEMS FOR INTEGRATED CIRCUITS - Structures and methods for forming the same. A semiconductor chip includes a substrate and a transistor. The chip includes N interconnect layers on the substrate, N being a positive integer. The chip includes a cooling pipes system inside the N interconnect layers. The cooling pipes system does not include any solid or liquid material. Given any first point and any second point in the cooling pipes system, there exists a continuous path which connects the first and second points and which is totally within the cooling pipes system. A first portion of the cooling pipes system overlaps the transistor. A second portion of the cooling pipes system is higher than the substrate and lower than a top interconnect layer. The second portion is in direct physical contact with a surrounding ambient. | 06-03-2010 |
20130012018 | ON-CHIP COOLING FOR INTEGRATED CIRCUITS - A semiconductor structure fabrication method. A provided structure includes: a semiconductor substrate, a transistor on the semiconductor substrate, N interconnect layers on the semiconductor substrate, and a temporary filling region within the N layers. N is at least 2. The temporary filling region is heated at a high temperature sufficiently high to result in the temporary filling material being replaced by a cooling pipes system that does not include any solid or liquid material. A first portion and a second portion of the cooling pipes system are each in direct physical contact with a surrounding ambient at a first interface and a second interface respectively such that a first direction perpendicular to the first interface is perpendicular to a second direction perpendicular to the second interface. A totality of interfaces between the cooling pipes system and the ambient consists of the first interface and the second interface. | 01-10-2013 |