Patent application number | Description | Published |
20080197424 | SEMICONDUCTOR STRUCTURE INCLUDING GATE ELECTRODE HAVING LATERALLY VARIABLE WORK FUNCTION - A semiconductor structure, such as a CMOS structure, includes a gate electrode that has a laterally variable work function. The gate electrode that has the laterally variable work function may be formed using an angled ion implantation method or a sequential layering method. The gate electrode that has the laterally variable work function provides enhanced electrical performance within an undoped channel field effect transistor device. | 08-21-2008 |
20080224256 | SEMICONDUCTOR-ON-INSULATOR(SOI) STRUCTURES INCLUDING GRADIENT NITRIDED BURIED OXIDE (BOX) - A semiconductor-on-insulator structure includes a buried dielectric layer interposed between a base semiconductor substrate and a surface semiconductor layer. The buried dielectric layer comprises an oxide material that includes a nitrogen gradient that peaks at the interface of the buried dielectric layer with at least one of the base semiconductor substrate and surface semiconductor layer. The interface of the buried dielectric layer with the at least one of the base semiconductor substrate and surface semiconductor layer is abrupt, providing a transition in less than about 5 atomic layer thickness, and having less than about 10 angstroms RMS interfacial roughness. A second dielectric layer comprising an oxide dielectric material absent nitrogen may be located interposed between the buried dielectric layer and the surface semiconductor layer | 09-18-2008 |
20080308867 | PARTIALLY DEPLETED SOI FIELD EFFECT TRANSISTOR HAVING A METALLIZED SOURCE SIDE HALO REGION - Source and drain extension regions and source side halo region and drain side halo region are formed in a top semiconductor layer aligned with a gate stack on an SOI substrate. A deep source region and a deep drain region are formed asymmetrically in the top semiconductor layer by an angled ion implantation. The deep source region is offset away from one of the outer edges of the at least spacer to expose the source extension region on the surface of the semiconductor substrate. A source metal semiconductor alloy is formed by reacting a metal layer with portions of the deep source region, the source extension region, and the source side halo region. The source metal semiconductor alloy abuts the remaining portion of the source side halo region, providing a body contact tied to the deep source region to the partially depleted SOI MOSFET. | 12-18-2008 |
20080315309 | FIN FIELD EFFECT TRANSISTOR DEVICES WITH SELF-ALIGNED SOURCE AND DRAIN REGIONS - Improved fin field effect transistor (FinFET) devices and methods for the fabrication thereof are provided. In one aspect, a method for fabricating a field effect transistor device comprises the following steps. A substrate is provided having a silicon layer thereon. A fin lithography hardmask is patterned on the silicon layer. A dummy gate structure is placed over a central portion of the fin lithography hardmask. A tiller layer is deposited around the dummy gate structure. The dummy gate structure is removed to reveal a trench in the filler layer, centered over the central portion of the fin lithography hardmask, that distinguishes a fin region of the device from source and drain regions of the device. The fin lithography hardmask in the fin region is used to etch a plurality of fins in the silicon layer. The trench is filled with a gate material to form a gate stack over the fins. The filler layer is removed to reveal the source and drain regions of the device, wherein the source and drain regions are intact and self-aligned with the gate stack. | 12-25-2008 |
20090219778 | BACK-GATE DECODE PERSONALIZATION - A novel methodology for the construction and operation of logical circuits and gates that makes use of and contact to a fourth (4 | 09-03-2009 |
20090295432 | CMOS BACK-GATED KEEPER TECHNIQUE - A novel methodology for the construction and operation of logical circuits and gates that make use of and contact to a fourth terminal (substrates/bodies) of MOSFET devices is described in detail. The novel construction and operation provides for maintaining such body-contacted MOSFET devices at a lower threshold voltage (V | 12-03-2009 |
20090302372 | Fin Field Effect Transistor Devices with Self-Aligned Source and Drain Regions - Improved fin field effect transistor (FinFET) devices and methods for the fabrication thereof are provided. In one aspect, a method for fabricating a field effect transistor device comprises the following steps. A substrate is provided having a silicon layer thereon. A fin lithography hardmask is patterned on the silicon layer. A dummy gate structure is placed over a central portion of the fin lithography hardmask. A filler layer is deposited around the dummy gate structure. The dummy gate structure is removed to reveal a trench in the filler layer, centered over the central portion of the fin lithography hardmask, that distinguishes a fin region of the device from source and drain regions of the device. The fin lithography hardmask in the fin region is used to etch a plurality of fins in the silicon layer. The trench is filled with a gate material to form a gate stack over the fins. The filler layer is removed to reveal the source and drain regions of the device, wherein the source and drain regions are intact and self-aligned with the gate stack. | 12-10-2009 |
20090309148 | SEMICONDUCTOR STRUCTURE INCLUDING GATE ELECTRODE HAVING LATERALLY VARIABLE WORK FUNCTION - A semiconductor structure, such as a CMOS structure, includes a gate electrode that has a laterally variable work function. The gate electrode that has the laterally variable work function may be formed using an angled ion implantation method or a sequential layering method. The gate electrode that has the laterally variable work function provides enhanced electrical performance within an undoped channel field effect transistor device. | 12-17-2009 |
20090321831 | PARTIALLY DEPLETED SOI FIELD EFFECT TRANSISTOR HAVING A METALLIZED SOURCE SIDE HALO REGION - Source and drain extension regions and source side halo region and drain side halo region are formed in a top semiconductor layer aligned with a gate stack on an SOI substrate. A deep source region and a deep drain region are formed asymmetrically in the top semiconductor layer by an angled ion implantation. The deep source region is offset away from one of the outer edges of the at least spacer to expose the source extension region on the surface of the semiconductor substrate. A source metal semiconductor alloy is formed by reacting a metal layer with portions of the deep source region, the source extension region, and the source side halo region. The source metal semiconductor alloy abuts the remaining portion of the source side halo region, providing a body contact tied to the deep source region to the partially depleted SOI MOSFET. | 12-31-2009 |
20120132989 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 05-31-2012 |
20120298965 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 11-29-2012 |
20130037885 | SEMICONDUCTOR-ON-INSULATOR (SOI) STRUCTURES INCLUDING GRADIENT NITRIDED BURIED OXIDE (BOX) - A semiconductor-on-insulator structure includes a buried dielectric layer interposed between a base semiconductor substrate and a surface semiconductor layer. The buried dielectric layer comprises an oxide material that includes a nitrogen gradient that peaks at the interface of the buried dielectric layer with at least one of the base semiconductor substrate and surface semiconductor layer. The interface of the buried dielectric layer with the at least one of the base semiconductor substrate and surface semiconductor layer is abrupt, providing a transition in less than about 5 atomic layer thickness, and having less than about 10 angstroms RMS interfacial roughness. A second dielectric layer comprising an oxide dielectric material absent nitrogen may be located interposed between the buried dielectric layer and the surface semiconductor layer. | 02-14-2013 |
20130161744 | FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A finFET device is provided. The finFET device includes a BOX layer, fin structures located over the BOX layer, a gate stack located over the fin structures, gate spacers located on vertical sidewalls of the gate stack, an epi layer covering the fin structures, source and drain regions located in the semiconductor layers of the fin structures, and silicide regions abutting the source and drain regions. The fin structures each comprise a semiconductor layer and extend in a first direction, and the gate stack extends in a second direction that is perpendicular. The gate stack comprises a high-K dielectric layer and a metal gate, and the epi layer merges the fin structures together. The silicide regions each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130164890 | METHOD FOR FABRICATING FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A method is provided for fabricating a finFET device. Fin structures are formed over a BOX layer. The fin structures include a semiconductor layer and extend in a first direction. A gate stack is formed on the BOX layer over the fin structures and extending in a second direction. The gate stack includes a high-K dielectric layer and a metal gate. Gate spacers are formed on sidewalls of the gate stack, and an epi layer is deposited to merge the fin structures. Ions are implanted to form source and drain regions, and dummy spacers are formed on sidewalls of the gate spacers. The dummy spacers are used as a mask to recess or completely remove an exposed portion of the epi layer. Silicidation forms silicide regions that abut the source and drain regions and each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130193513 | Multi-Gate Field Effect Transistor with a Tapered Gate Profile - A multi-gate field effect transistor apparatus and method for making same. The apparatus includes a source terminal, a drain terminal, and a gate terminal which includes a tapered-gate profile. A method for designing a multi-gate field effect transistor includes arranging a source terminal, a drain terminal and a gate terminal with a tapered-gate profile to create a wider gate width on a bottom of a fin. | 08-01-2013 |
20130198695 | Multi-Gate Field Effect Transistor with A Tapered Gate Profile - A multi-gate field effect transistor apparatus and method for making same. The apparatus includes a source terminal, a drain terminal, and a gate terminal which includes a tapered-gate profile. A method for designing a multi-gate field effect transistor includes arranging a source terminal, a drain terminal and a gate terminal with a tapered-gate profile to create a wider gate width on a bottom of a fin. | 08-01-2013 |
20140042556 | Fin Field Effect Transistor Devices With Self-Aligned Source and Drain Regions - Improved fin field effect transistor (FinFET) devices and methods for the fabrication thereof are provided. In one aspect, a field effect transistor device is provided. The field effect transistor device includes a source region; a drain region; a plurality of fins connecting the source region and the drain region, the fins having a pitch of between about 40 nanometers and about 200 nanometers and each fin having a width of between about ten nanometers and about 40 nanometers; and a gate stack over at least a portion of the fins, wherein the source region and the drain region are self-aligned with the gate stack. | 02-13-2014 |
20140339502 | ELEMENTAL SEMICONDUCTOR MATERIAL CONTACT FOR HIGH INDIUM CONTENT InGaN LIGHT EMITTING DIODES - A vertical stack including a p-doped GaN portion, a multi-quantum-well including indium gallium nitride layers, and an n-doped transparent conductive material portion is formed on an insulator substrate. A dielectric material liner is formed around the vertical stack, and is patterned to physically expose a surface of the p-doped GaN portion. A selective low temperature epitaxy process is employed to deposit a semiconductor material including at least one elemental semiconductor material on the physically exposed surfaces of the p-doped GaN portion, thereby forming an elemental semiconductor material portion. The selective low temperature epitaxy process can be performed at a temperature lower than 600° C., thereby limiting diffusion of materials within the multi-quantum well and avoiding segregation of indium within the multi-quantum well. The light-emitting diode can generate a radiation of a wide range including blue and green lights in the visible wavelength range. | 11-20-2014 |
20140342485 | ELEMENTAL SEMICONDUCTOR MATERIAL CONTACT FOR HIGH INDIUM CONTENT InGaN LIGHT EMITTING DIODES - A vertical stack including a p-doped GaN portion, a multi-quantum-well including indium gallium nitride layers, and an n-doped transparent conductive material portion is formed on an insulator substrate. A dielectric material liner is formed around the vertical stack, and is patterned to physically expose a surface of the p-doped GaN portion. A selective low temperature epitaxy process is employed to deposit a semiconductor material including at least one elemental semiconductor material on the physically exposed surfaces of the p-doped GaN portion, thereby forming an elemental semiconductor material portion. The selective low temperature epitaxy process can be performed at a temperature lower than 600° C., thereby limiting diffusion of materials within the multi-quantum well and avoiding segregation of indium within the multi-quantum well. The light-emitting diode can generate a radiation of a wide range including blue and green lights in the visible wavelength range. | 11-20-2014 |