Abstract: A silicon on insulator (SOI) multi-gate field effect transistor electrically Programmable Read-Only Memory (MuFET EPROM) includes a substrate having a dielectric surface. A first semiconducting region is in or on the dielectric surface. A source region, a drain region and a channel region interposed between the source and drain are formed in first semiconducting region. A gate dielectric layer is on the channel region. At least a second semiconducting region in or on the dielectric surface is spaced apart from the first semiconducting region. A first electrode layer comprises a first electrode portion including a transistor gate electrode and a control gate electrode electrically isolated from one another. The transistor gate overlies the channel region to form a transistor. The control gate extends to overlay a portion of the second semiconducting region.

Abstract: One embodiment of the present invention relates to a memory cell. The memory cell includes a multi-gate field effect transistor associated with a first region of a semiconductor fin. The memory cell also includes a fin capacitor coupled to a drain of the multi-gate field effect transistor and associated with a second region of the semiconductor fin, where the fin capacitor has an approximately degenerate doping concentration in the second region. Other devices and methods are also disclosed.

Abstract: Different performance MOSFET Fully Depleted devices can be achieved on a single chip by varying the Vt through ion implantation. The integration of multiple Vt can be achieved through the selection of a metal gate stack with suitable effective WF for one semiconductor device to be included on a chip. Then, an ion implantation, with a dopant such as F, can be selectively performed to achieve proper Vt for other semiconductor devices on the chip.

Abstract: Exemplary embodiments provide methods and structures for controlling work function values of dual metal gate electrodes for transistor devices. Specifically, the work function value of one of the PMOS and NMOS metal gate electrodes can be controlled by a reaction between stacked layers deposited on a gate dielectric material. The stacked layers can include a first-metal-containing material such as Al2O3, and/or AlN overlaid by a second-metal-containing material such as TaN, TiN, WN, MoN or their respective metals. The reaction between the stacked layers can create a metal gate material with a desired work function value ranging from about 4.35 eV to about 5.0 eV. The disclosed methods and structures can be used for CMOS transistors including MOSFET devices formed on a bulk substrate, and planar FET devices or 3-D MuGFET devices (e.g., FinFET devices) formed upon the oxide insulator of a SOI.

Abstract: A semiconductor device includes a semiconductor substrate, a dielectric layer on the substrate, and a gate on the dielectric layer. The gate has first and second ends containing a first material, a middle region between the first and second ends containing a second material. The first material has a different work function than the second material.

Abstract: A method for semiconductor processing provides a DSB semiconductor body having a first crystal orientation, a second crystal orientation, and a border region disposed between the first and second crystal orientations. The border region further has a defect associated with an interface of the first crystal orientation and second the second crystal orientation, wherein the defect generally extends a distance into the semiconductor body from a surface of the body. A sacrificial portion of the semiconductor body is removed from the surface thereof, wherein removing the sacrificial portion at least partially removes the defect. The sacrificial portion can be defined by oxidizing the surface at low temperature, wherein the oxidation at least partially consumes the defect. The sacrificial portion can also be removed by CMP. An STI feature may be further formed over the defect after removal of the sacrificial portion, therein consuming any remaining defect.

Abstract: One embodiment of the present invention relates to a memory cell. The memory cell includes a multi-gate field effect transistor associated with a first region of a semiconductor fin. The memory cell also includes a fin capacitor coupled to a drain of the multi-gate field effect transistor and associated with a second region of the semiconductor fin, where the fin capacitor has an approximately degenerate doping concentration in the second region. Other devices and methods are also disclosed.

Abstract: An STI field oxide element in an IC which includes a layer of epitaxial semiconductor on sidewalls of the STI trench to increase the width of the active area adjacent to the STI trench and decrease a width of dielectric material in the STI trench is disclosed. STI etch residue is removed from the STI trench surface prior to growth of the epitaxial layer. The epitaxial semiconductor composition is matched to the composition of the adjacent active area. The epitaxial semiconductor may be undoped or doped to match the active area. The STI trench with the epitaxial layer is compatible with common STI passivation and fill processes. The thickness of the as-grown epitaxial semiconductor layer is selected to provide a desired active area width or a desired STI dielectric width.

Abstract: A method of forming reduced width STI field oxide elements using sidewall spacers on the isolation hardmask to reduce the STI trench width is disclosed. The isolation sidewall spacers are formed by depositing a conformal layer of spacer material on the isolation hardmask and performing an anisotropic etch. The isolation sidewall spacers reduce the exposed substrate width during the subsequent STI trench etch process, leading to a reduced STI trench width. A method of forming the isolation sidewall spacers of a material that is easily removed from the isolation hardmask to provide an exposed shoulder width on the substrate defined by the sidewall thickness is also disclosed.

Abstract: A method of forming an integrated circuit device that includes a plurality of MuGFETs is disclosed. A PMOS fin of a MuGFET is formed on a substrate. The PMOS fin includes a channel of a first surface of a first crystal orientation. A NMOS fin of another MuGFET is formed on the substrate. The NMOS fin includes a channel on the substrate at one of 0° and 90° to the PMOS fin and includes a second surface of a second crystal orientation.

Abstract: One embodiment of the present invention relates to an integrated circuit that includes a first multi-gate transistor that has a first fin width and a first threshold voltage. The integrated circuit also includes a second multi-gate transistor that has a second fin width that is greater than the first width and a second threshold voltage that is less than the first threshold voltage. Other circuits and methods are also disclosed.

Abstract: A semiconductor device comprising a first transistor device and second transistor device both on a semiconductor substrate. The first transistor device has a first n-channel and a first p-channel and the second transistor device has a second n-channel and a second p-channel. Each of the p-channels and the n-channels have a long lateral axis that is aligned with a orientation plane of a silicon layer of the semiconductor substrate. The second p-channel and the first and second n-channels include the silicon layer configured as strained silicon. The first p-channel includes the silicon layer configured as relaxed silicon. Each of the n-channels contact gate structures that impart a tensile stress in the n-channels.

Abstract: Exemplary embodiments provide methods and structures for controlling work function values of dual metal gate electrodes for transistor devices. Specifically, the work function value of one of the PMOS and NMOS metal gate electrodes can be controlled by a reaction between stacked layers deposited on a gate dielectric material. The stacked layers can include a first-metal-containing material such as Al2O3, and/or AlN overlaid by a second-metal-containing material such as TaN, TiN, WN, MoN or their respective metals. The reaction between the stacked layers can create a metal gate material with a desired work function value ranging from about 4.35 eV to about 5.0 eV. The disclosed methods and structures can be used for CMOS transistors including MOSFET devices formed on a bulk substrate, and planar FET devices or 3-D MuGFET devices (e.g., FinFET devices) formed upon the oxide insulator of a SOI.

Abstract: One embodiment of the present invention relates to a method of fabricating a multi-gate transistor. During the method a second gate electrode material is selectively removed from a semiconductor structure from which the multi-gate transistor is formed, thereby exposing at least one surface of a first gate electrode material. The exposed surface of the first gate electrode material is deglazed. Subsequently, the first gate electrode material is removed. Other methods and devices are also disclosed.

Abstract: A semiconductor device comprising a first multi-gate device and a second multi-gate device on a semiconductor substrate. The first multi-gate device comprising a first gate structure and the second multi-gate device comprises a second gate structure. An effective width of the first gate structure is greater than an effective width of the second gate structure.

Abstract: A semiconductor device comprising a first multi-gate device and a second multi-gate device on a semiconductor substrate. The first multi-gate device comprising a first gate structure and the second multi-gate device comprises a second gate structure. An effective width of the first gate structure is greater than an effective width of the second gate structure.

Abstract: The formation of one or more accumulation mode multi gate transistor devices is disclosed. The devices are formed so that short channel effects are mitigated. In particular, one more types of dopant materials are implanted in a channel region, an extension region and/or source/drain regions to mitigate the establishment of a conduction path and the accumulation of electrons in the channel region that can result in an unwanted leakage current.

Abstract: According to one embodiment of the invention, a method for integrating low Schottky barrier metal source/drain includes providing a substrate, forming an epitaxial SiGe layer outwardly from the substrate, forming an epitaxial Si layer outwardly from the SiGe layer, and forming a metal source and a metal drain.

Abstract: The present invention provides a metal oxide semiconductor (MOS) device, a method of manufacture therefore, and an integrated circuit including the same. The metal oxide semiconductor (MOS) device (100), without limitation, may include a first accumulation mode transistor device (120, 160) located over or in a substrate (110), as well as a second enhancement mode transistor (140, 180) device located over or in the substrate (110).

Abstract: The formation of one or more accumulation mode multi gate transistor devices is disclosed. The devices are formed so that short channel effects are mitigated. In particular, one more types of dopant materials are implanted in a channel region, an extension region and/or source/drain regions to mitigate the establishment of a conduction path and the accumulation of electrons in the channel region that can result in an unwanted leakage current.