Abstract: A method for fabrication of 3D semiconductor devices utilizing a layer transfer and steps for forming transistors on top of a pre-fabricated semiconductor device comprising transistors formed on crystallized semiconductor base layer and metal layer for the transistors interconnections and insulation layer. The advantage of this approach is reduction of the over all metal length used to interconnect the various transistors.

Abstract: A Configurable device comprising, a logic die connected by at least one through silicon-via (TSV), to an input/output (I/O) die.

Abstract: A semiconductor device comprising: a first single crystal silicon layer comprising first transistors, first alignment marks, and at least one metal layer overlying the first single crystal silicon layer, wherein the at least one metal layer comprises copper or aluminum more than other materials; and a second single crystal silicon layer overlying the at least one metal layers; wherein the second single crystal silicon layer comprises a plurality of second transistors arranged in substantially parallel bands wherein each of a plurality of the bands comprises a portion of the second transistors along an axis in a repeating pattern.

Abstract: A method for fabrication of 3D semiconductor devices utilizing a layer transfer and steps for forming transistors on top of a pre-fabricated semiconductor device comprising transistors formed on crystallized semiconductor base layer and metal layer for the transistors interconnections and insulation layer. The advantage of this approach is reduction of the over all metal length used to interconnect the various transistors.

Abstract: A method of manufacturing a semiconductor wafer, the method comprising: providing a base wafer comprising a semiconductor substrate, metal layers and first alignment marks; transferring a monocrystalline layer on top of said metal layers, wherein said monocrystalline layer comprises second alignment marks; and performing a lithography using an alignment based on a misalignment between said first alignment marks and said second alignment marks.

Abstract: A semiconductor device includes a first single crystal silicon layer including first transistors, a first alignment mark, and at least one metal layer overlying the first single crystal silicon layer for interconnecting the first transistors; a second layer overlying the at least one metal layer, wherein the second layer includes a plurality of second transistors; and a connection path connecting the first transistors and the second transistors and including at least a first strip, a second strip, and a through via connecting the first strip and the second strip, wherein the second strip is substantially orthogonal to the first strip and wherein the through via is substantially away from both ends of the first strip and both ends of the second strip.

Abstract: A semiconductor device includes a first mono-crystallized layer including first transistors, and a first metal layer forming at least a portion of connections between the first transistors; and a second layer including second transistors, the second transistors including mono-crystalline material, the second layer overlying the first metal layer, wherein the first metal layer includes aluminum or copper, and wherein the second layer is less than one micron in thickness and includes logic cells.

Abstract: A semiconductor device includes a first mono-crystallized layer including first transistors, and a first metal layer forming at least a portion of connections between the first transistors; and a second layer including second transistors, the second transistors including mono-crystalline material, the second layer overlying the first metal layer, wherein the first metal layer includes aluminum or copper, and wherein the second layer is less than one micron in thickness and includes logic cells.

Abstract: A system includes a semiconductor device. The semiconductor device includes a first single crystal silicon layer comprising first transistors, first alignment marks, and at least one metal layer overlying the first single crystal silicon layer, wherein the at least one metal layer comprises copper or aluminum more than other materials; and a second single crystal silicon layer overlying the at least one metal layer. The second single crystal silicon layer comprises a plurality of second transistors arranged in substantially parallel bands. Each of a plurality of the bands comprises a portion of the second transistors along an axis in a repeating pattern.

Abstract: A system includes a semiconductor device. The semiconductor device includes a first single crystal silicon layer comprising first transistors, first alignment marks, and at least one metal layer overlying the first single crystal silicon layer, wherein the at least one metal layer comprises copper or aluminum more than other materials; and a second single crystal silicon layer overlying the at least one metal layer. The second single crystal silicon layer comprises a plurality of second transistors arranged in substantially parallel bands. Each of a plurality of the bands comprises a portion of the second transistors along an axis in a repeating pattern.

Abstract: A method is presented that may be used to provide a Configurable Logic device, which may be Field Programmable with volume flexibility. A method of fabricating an integrated circuit may include the steps of: providing a semiconductor substrate and forming a borderless logic array, and it may also include the step of forming a plurality of antifuse configurable interconnect circuits and/or a plurality of transistors to configure at least one antifuse. The programming transistors may be fabricated over the at least one antifuse.

Abstract: A method for fabrication of 3D semiconductor devices utilizing a layer transfer and steps for forming transistors on top of a pre-fabricated semiconductor device comprising transistors formed on crystallized semiconductor base layer and metal layer for the transistors interconnections and insulation layer. The advantage of this approach is reduction of the over all metal length used to interconnect the various transistors.

Abstract: A method of manufacturing a semiconductor wafer, the method comprising: providing a base wafer comprising a semiconductor substrate, metal layers and first alignment marks; transferring a monocrystalline layer on top of said metal layers, wherein said monocrystalline layer comprises second alignment marks; and performing a lithography using an alignment based on a misalignment between said first alignment marks and said second alignment marks.

Abstract: A semiconductor device comprising: a first single crystal silicon layer comprising first transistors, first alignment marks, and at least one metal layer overlying the first single crystal silicon layer, wherein the at least one metal layer comprises copper or aluminum more than other materials; and a second single crystal silicon layer overlying the at least one metal layers; wherein the second single crystal silicon layer comprises a plurality of second transistors arranged in substantially parallel bands wherein each of a plurality of the bands comprises a portion of the second transistors along an axis in a repeating pattern.

Abstract: A method of layer formation on a substrate with high aspect ratio features is disclosed. The layer is formed from a gas mixture comprising one or more process gases and one or more etch species. The one or more process gases react to deposit a material layer on the substrate. In conjunction with the material layer deposition, the etch species selectively remove portions of the deposited material layer adjacent to high aspect ratio feature openings, filling such features in a void-free and/or seam-free manner. The material layer may be deposited on the substrate using physical vapor deposition (PVD) and/or chemical vapor deposition (CVD) techniques.

Abstract: Methods for forming a denuded zone in an oxygen-containing semiconductor wafer using rapid laser annealing (RLA) are disclosed. The method includes scanning an intense beam of laser radiation over the surface of the wafer to raise the temperature of each point on the wafer surface to be at or near the wafer's melting temperature for a time period on the order of a millisecond or so. This rapid heating and cooling causes oxygen in the wafer near the wafer surface to diffuse out from the wafer surface. Oxygen in the body of the wafer remains unheated and thus does not diffuse toward the wafer surface. The result is an oxygen-depleted zone—called a “denuded zone”—formed immediately adjacent the wafer surface. The methods further include forming a semiconductor device feature in the denuded zone such as by implanting the wafer with dopants.

Abstract: Methods for forming a denuded zone in an oxygen-containing semiconductor wafer using rapid laser annealing (RLA) are disclosed. The method includes scanning an intense beam of laser radiation over the surface of the wafer to raise the temperature of each point on the wafer surface to be at or near the wafer's melting temperature for a time period on the order of a millisecond or so. This rapid heating and cooling causes oxygen in the wafer near the wafer surface to diffuse out from the wafer surface. Oxygen in the body of the wafer remains unheated and thus does not diffuse toward the wafer surface. The result is an oxygen-depleted zone—called a “denuded zone”—formed immediately adjacent the wafer surface. The methods further include forming a semiconductor device feature in the denuded zone such as by implanting the wafer with dopants.

Abstract: A method of layer formation on a substrate with high aspect ratio features is disclosed. The layer is formed from a gas mixture comprising one or more process gases and one or more etch species. The one or more process gases react to deposit a material layer on the substrate. In conjunction with the material layer deposition, the etch species selectively remove portions of the deposited material layer adjacent to high aspect ratio feature openings, filling such features in a void-free and/or seam-free manner. The material layer may be deposited on the substrate using physical vapor deposition (PVD) and/or chemical vapor deposition (CVD) techniques.

Abstract: One embodiment of the present invention is a process tool optimization system that includes: (a) a data mining engine that analyzes end-of-line yield data to identify one or more process tools associated with low yield; and (b) in response to output from the analysis, analyzes process tool data from the one or more process tools to identify one or more process tool parameters associated with the low yield.

Abstract: A method of layer formation on a substrate with high aspect ratio features is disclosed. The layer is formed from a gas mixture comprising one or more process gases and one or more etch species. The one or more process gases react to deposit a material layer on the substrate. In conjunction with the material layer deposition, the etch species selectively remove portions of the deposited material layer adjacent to high aspect ratio feature openings, filling such features in a void-free and/or seam-free manner. The material layer may be deposited on the substrate using physical vapor deposition (PVD) and/or chemical vapor deposition (CVD) techniques.