Abstract: A buried plate region for a semiconductor memory storage capacitor is self aligned with respect to an upper portion of a deep trench containing the memory storage capacitor.

Abstract: A method of forming crystalline Si:C in source and drain regions is provided. After formation of shallow trench isolation and gate electrodes of field effect transistors, gate spacers are formed on gate electrodes. Preamorphization implantation is performed in the source and drain regions, followed by carbon implantation. The upper portion of the source and drain regions comprises an amorphous mixture of silicon, germanium, and/or carbon. An anti-reflective layer is deposited to enhance the absorption of a laser beam into the silicon substrate. The laser beam is scanned over the silicon substrate including the upper source and drain region with the amorphous mixture. The energy of the laser beam is controlled so that the temperature of the semiconductor substrate is above the melting temperature of the amorphous mixture but below the glass transition temperature of silicon oxide so that structural integrity of the semiconductor structure is preserved.

Abstract: In one embodiment, the invention is a complementary metal-oxide-semiconductor device with an embedded stressor. One embodiment of a field effect transistor includes a silicon on insulator channel, a gate electrode coupled to the silicon on insulator channel, and a stressor embedded in the silicon on insulator channel and spaced laterally from the gate electrode, where the stressor is formed of a silicon germanide alloy whose germanium content gradually increases in one direction.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for fabricating low-defect-density hybrid orientation substrates. ATR methods for hybrid orientation substrate fabrication generally start with a Si layer having a first orientation bonded to a second Si layer or substrate having a second orientation. Selected regions of the first Si layer are amorphized and then recrystallized into the orientation of the second Si layer by using the second Si layer as a template. In particular, this invention provides a melt-recrystallization ATR method, for use alone or in combination with non-melt-recrystallization ATR methods, in which selected Si regions bounded by dielectric-filled trenches are induced to undergo an orientation change by the steps of preamorphization, laser-induced melting, and corner-defect-free templated recrystallization from the melt.

Abstract: An SRAM having asymmetrical FET pass gates and a method of fabricating an SRAM having asymmetrical FET pass gates. The pass gates are asymmetrical with respect to current conduction from the drain to the source of the pass gate being different from current conduction from the source to the drain of the pass gate.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template.

Abstract: A PFET is provided on a silicon layer having a (110) surface orientation and located in a substrate. A compressive stress liner disposed on the gate and source/drain regions of the PFET generates a primary longitudinal compressive strain along the direction of the PFET channel. A tensile stress liner disposed on at least one NFET located transversely adjacent to the PFET generates a primary longitudinal tensile strain along the direction of the NFET channel. A secondary stress field from the at least one NFET tensile liner generates a beneficial transverse tensile stress in the PFET channel. The net benefits of the primary compressive longitudinal strain and the secondary tensile transverse stress are maximized when the azimuthal angle between the direction of the PFET channel and an in-plane [1 1 0] crystallographic direction in the (110) silicon layer is from about 25° to about 55.

Abstract: A method of forming crystalline Si:C in source and drain regions is provided. After formation of shallow trench isolation and gate electrodes of field effect transistors, gate spacers are formed on gate electrodes. Preamorphization implantation is performed in the source and drain regions, followed by carbon implantation. The upper portion of the source and drain regions comprises an amorphous mixture of silicon, germanium, and/or carbon. An anti-reflective layer is deposited to enhance the absorption of a laser beam into the silicon substrate. The laser beam is scanned over the silicon substrate including the upper source and drain region with the amorphous mixture. The energy of the laser beam is controlled so that the temperature of the semiconductor substrate is above the melting temperature of the amorphous mixture but below the glass transition temperature of silicon oxide so that structural integrity of the semiconductor structure is preserved.

Abstract: A PFET is provided on a silicon layer having a (110) surface orientation and located in a substrate. A compressive stress liner disposed on the gate and source/drain regions of the PFET generates a primary longitudinal compressive strain along the direction of the PFET channel. A tensile stress liner disposed on at least one NFET located transversely adjacent to the PFET generates a primary longitudinal tensile strain along the direction of the NFET channel. A secondary stress field from the at least one NFET tensile liner generates a beneficial transverse tensile stress in the PFET channel. The net benefits of the primary compressive longitudinal strain and the secondary tensile transverse stress are maximized when the azimuthal angle between the direction of the PFET channel and an in-plane [1 10] crystallographic direction in the (110) silicon layer is from about 25° to about 55.

Abstract: A method of reducing contact resistance on a silicon-on-insulator includes exposing sidewalls and a portion of a top surface of a source/drain region of the device, forming a porous silicon layer within a surface of the source/drain region, implanting dopants in the source/drain region, and forming a silicide layer over the source/drain region. The porous silicon layer is formed by forming a layer of p+ doping on the exposed sidewalls and portion of the top surface of the source/drain region, forming a nitride liner over the device, including the source/drain region and the layer of p+ doping, forming a planarized resist over the nitride liner, recessing the planarized resist and etching the nitride liner to expose portions of the source/drain region, and forming the porous silicon layer on the exposed portions of the source drain region.

Abstract: An SRAM having asymmetrical FET pass gates and a method of fabricating an SRAM having asymmetrical FET pass gates. The pass gates are asymmetrical with respect to current conduction from the drain to the source of the pass gate being different from current conduction from the source to the drain of the pass gate.

Abstract: Hybrid orientation substrates allow the fabrication of complementary metal oxide semiconductor (CMOS) circuits in which the n-type field effect transistors (nFETs) are disposed in a semiconductor orientation which is optimal for electron mobility and the p-type field effect transistors (pFETs) are disposed in a semiconductor orientation which is optimal for hole mobility. This invention discloses that the performance advantages of FETs formed entirely in the optimal semiconductor orientation may be achieved by only requiring that the device's channel be disposed in a semiconductor with the optimal orientation. A variety of new FET structures are described, all with the characteristic that at least some part of the FET's channel has a different orientation than at least some part of the FET's source and/or drain. Hybrid substrates into which these new FETs might be incorporated are described along with their methods of making.

Abstract: The present invention provides a semiconductor material that has enhanced electron and hole mobilities that comprises a Si-containing layer having a <110> crystal orientation and a biaxial compressive strain. The term “biaxial compressive stress” is used herein to describe the net stress caused by longitudinal compressive stress and lateral stress that is induced upon the Si-containing layer during the manufacturing of the semiconductor material. Other aspect of the present invention relates to a method of forming the semiconductor material of the present invention. The method of the present invention includes the steps of providing a silicon-containing <110> layer; and creating a biaxial strain in the silicon-containing <110> layer.

Abstract: The present invention provides a semiconductor structure in which different types of devices are located upon a specific crystal orientation of a hybrid substrate that enhances the performance of each type of device. In the semiconductor structure of the present invention, a dual trench isolation scheme is employed whereby a first trench isolation region of a first depth isolates devices of different polarity from each other, while second trench isolation regions of a second depth, which is shallower than the first depth, are used to isolate devices of the same polarity from each other. The present invention further provides a dual trench semiconductor structure in which pFETs are located on a (110) crystallographic plane, while nFETs are located on a (100) crystallographic plane. In accordance with the present invention, the devices of different polarity, i.e., nFETs and pFETs, are bulk-like devices.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for fabricating low-defect-density hybrid orientation substrates. ATR methods for hybrid orientation substrate fabrication generally start with a Si layer having a first orientation bonded to a second Si layer or substrate having a second orientation. Selected regions of the first Si layer are amorphized and then recrystallized into the orientation of the second Si layer by using the second Si layer as a template. In particular, this invention provides a melt-recrystallization ATR method, for use alone or in combination with non-melt-recrystallization ATR methods, in which selected Si regions bounded by dielectric-filled trenches are induced to undergo an orientation change by the steps of preamorphization, laser-induced melting, and corner-defect-free templated recrystallization from the melt.

Abstract: Integrated circuits are oriented on a substrate at an angle that is rotated between 5 to 40 degrees from a direction parallel or perpendicular to a preferred crystalline plane direction, such as the cleavage plane, of the substrate. Parameters such as stress and mobility of transistors may be optimized by adjusting the angle of rotation of the substrate. For a rotated substrate CMOS device design, other stress control measures may be used, such as a stress control or tensile liner, over an NMOS transistor, PMOS transistor, or both, to further adjust the stress and improve performance.

Abstract: A method (and system) of reducing contact resistance on a silicon-on-insulator device, including controlling a silicide depth in a source-drain region of the device.

Abstract: A method (and system) of reducing contact resistance on a silicon-on-insulator device, including controlling a silicide depth in a source-drain region of the device.

Abstract: A hybrid orientation direct-semiconductor-bond (DSB) substrate with shallow trench isolation (STI) that is self-aligned to recrystallization boundaries is formed by patterning a hard mask layer for STI, a first amorphization implantation into openings in the hard mask layer, lithographic patterning of portions of a top semiconductor layer, a second amorphization implantation into exposed portions of the DSB substrate, recrystallization of the portions of the top semiconductor layer, and formation of STI utilizing the pattern in the hard mask layer. The edges of patterned photoresist for the second amorphization implantation are located within the openings in the patterned hard mask layer. Defective boundary regions formed underneath the openings in the hard mask layer are removed during the formation of STI to provide a leakage path free substrate. Due to elimination of a requirement for increased STI width, device density is increased compared to non-self-aligning process integration schemes.

Abstract: The present invention discloses the use of edge-angle-optimized solid phase epitaxy for forming hybrid orientation substrates comprising changed-orientation Si device regions free of the trench-edge defects typically seen when trench-isolated regions of Si are recrystallized to the orientation of an underlying single-crystal Si template after an amorphization step. For the case of amorphized Si regions recrystallizing to (100) surface orientation, the trench-edge-defect-free recrystallization of edge-angle-optimized solid phase epitaxy may be achieved in rectilinear Si device regions whose edges align with the (100) crystal's in-plane <100> directions.