Patent application number | Description | Published |
20080199998 | PRE-EPITAXIAL DISPOSABLE SPACER INTEGRATION SCHEME WITH VERY LOW TEMPERATURE SELECTIVE EPITAXY FOR ENHANCED DEVICE PERFORMANCE - The embodiments of the invention provide a method, etc. for a pre-epitaxial disposable spacer integration scheme with very low temperature selective epitaxy for enhanced device performance. More specifically, one method begins by forming a first gate and a second gate on a substrate. Next, an oxide layer is formed on the first and second gates; and, a nitride layer is formed on the oxide layer. Portions of the nitride layer proximate the first gate, portions of the oxide layer proximate the first gate, and portions of the substrate proximate the first gate are removed so as to form source and drain recesses proximate the first gate. Following this, the method removes remaining portions of the nitride layer, including exposing remaining portions of the oxide layer. The removal of the remaining portions of the nitride layer only exposes the remaining portions of the oxide layer and the source and drain recesses. | 08-21-2008 |
20080220588 | STRAINED Si MOSFET ON TENSILE-STRAINED SiGe-ON-INSULATOR (SGOI) - A semiconductor structure for use as a template for forming high-performance metal oxide semiconductor field effect transistor (MOSFET) devices is provided. More specifically, the present invention provides a structure that includes a SiGe-on-insulator substrate including a tensile-strained SiGe alloy layer located atop an insulating layer; and a strained Si layer atop the tensile-strained SiGe alloy layer. The present invention also provides a method of forming the tensile-strained SGOI substrate as well as the heterostructure described above. The method of the present invention decouples the preference for high strain in the strained Si layer and the Ge content in the underlying layer by providing a tensile-strained SiGe alloy layer directly atop on an insulating layer. | 09-11-2008 |
20080224218 | CMOS STRUCTURE INCLUDING DIFFERENTIAL CHANNEL STRESSING LAYER COMPOSITIONS - A CMOS structure includes an n-FET device comprising an n-FET channel region and a p-FET device comprising a p-FET channel region. The n-FET channel region includes a first silicon material layer located upon a silicon-germanium alloy material layer. The p-FET channel includes a second silicon material layer located upon a silicon-germanium-carbon alloy material layer. The silicon-germanium alloy material layer induces a desirable tensile strain within the n-FET channel. The silicon-germanium-carbon alloy material layer suppresses an undesirable tensile strain within the p-FET channel region. A silicon-germanium-carbon alloy material from which is comprised the silicon-germanium-carbon alloy material layer may be formed by selectively incorporating carbon into a silicon-germanium alloy material from which is formed the silicon-germanium alloy material layer. | 09-18-2008 |
20080251813 | HETERO-INTEGRATED STRAINED SILICON n- AND p- MOSFETS - The present invention provides semiconductor structures and a method of fabricating such structures for application of MOSFET devices. The semiconductor structures are fabricated in such a way so that the layer structure in the regions of the wafer where n-MOSFETs are fabricated is different from the layer structure in regions of the wafers where p-MOSFETs are fabricated. The structures are fabricated by first forming a damaged region with a surface of a Si-containing substrate by ion implanting of a light atom such as He. A strained SiGe alloy is then formed on the Si-containing substrate containing the damaged region. An annealing step is then employed to cause substantial relaxation of the strained SiGe alloy via a defect initiated strain relaxation. Next, a strained semiconductor cap such as strained Si is formed on the relaxed SiGe alloy. | 10-16-2008 |
20080268600 | MOSFET STRUCTURE WITH MULTIPLE SELF-ALIGNED SILICIDE CONTACTS - A metal oxide semiconductor field effect transistor (MOSFET) structure that includes multiple and distinct self-aligned silicide contacts and methods of fabricating the same are provided. The MOSFET structure includes at least one metal oxide semiconductor field effect transistor having a gate conductor including a gate edge located on a surface of a Si-containing substrate; a first inner silicide having an edge that is substantially aligned to the gate edge of the at least one metal oxide semiconductor field effect transistor; and a second outer silicide located adjacent to the first inner silicide. In accordance with the present invention, the second outer silicide has second thickness is greater than the first thickness of the first inner silicide. Moreover, the second outer silicide has a resistivity that is lower than the resistivity of the first inner silicide. | 10-30-2008 |
20080283918 | Ultra Thin Channel (UTC) MOSFET Structure Formed on BOX Regions Having Different Depths and Different Thicknesses Beneath the UTC and SourceDrain Regions and Method of Manufacture Thereof - A MOSFET structure includes a planar semiconductor substrate, a gate dielectric and a gate. A UT SOI channel extends to a first depth below the top surface of the substrate and is self-aligned to and is laterally coextensive with the gate. Source-drain regions, extend to a second depth greater than the first depth below the top surface, and are self-aligned to the UT channel region. A BOX | 11-20-2008 |
20080283934 | SUBSTANTIALLY L-SHAPED SILICIDE FOR CONTACT AND RELATED METHOD - A structure, semiconductor device and method having a substantially L-shaped silicide element for a contact are disclosed. The substantially L-shaped silicide element, inter alia, reduces contact resistance and may allow increased density of CMOS circuits. In one embodiment, the structure includes a substantially L-shaped silicide element including a base member and an extended member, wherein the base member extends at least partially into a shallow trench isolation (STI) region such that a substantially horizontal surface of the base member directly contacts a substantially horizontal surface of the STI region; and a contact contacting the substantially L-shaped silicide element. The contact may include a notch region for mating with the base member and a portion of the extended member, which increases the silicide-to-contact area and reduces contact resistance. Substantially L-shaped silicide element may be formed about a source/drain region, which increases the silicon-to-silicide area, and reduces crowding and contact resistance. | 11-20-2008 |
20090039461 | FORMATION OF IMPROVED SOI SUBSTRATES USING BULK SEMICONDUCTOR WAFERS - The present invention relates to a semiconductor-on-insulator (SOI) substrate having one or more device regions. Each device region comprises at least a base semiconductor substrate layer and a semiconductor device layer with a buried insulator layer located therebetween, while the semiconductor device layer is supported by one or more vertical insulating pillars. The vertical insulating pillars each preferably has a ledge extending between the base semiconductor substrate layer and the semiconductor device layer. The SOI substrates of the present invention can be readily formed from a precursor substrate structure with a “floating” semiconductor device layer that is spaced apart from the base semiconductor substrate layer by an air gap and is supported by one or more vertical insulating pillars. The air gap is preferably formed by selective removal of a sacrificial layer located between the base semiconductor substrate layer and the semiconductor device layer. | 02-12-2009 |
20090305474 | STRAINED-SILICON CMOS DEVICE AND METHOD - The present invention provides a semiconductor device and a method of forming thereof, in which a uniaxial strain is produced in the device channel of the semiconductor device. The uniaxial strain may be in tension or in compression and is in a direction parallel to the device channel. The uniaxial strain can be produced in a biaxially strained substrate surface by strain inducing liners, strain inducing wells or a combination thereof. The uniaxial strain may be produced in a relaxed substrate by the combination of strain inducing wells and a strain inducing liner. The present invention also provides a means for increasing biaxial strain with strain inducing isolation regions. The present invention further provides CMOS devices in which the device regions of the CMOS substrate may be independently processed to provide uniaxially strained semiconducting surfaces in compression or tension. | 12-10-2009 |
20100013024 | HIGH PERFORMANCE STRESS-ENHANCE MOSFET AND METHOD OF MANUFACTURE - The invention relates to a semiconductor structure and method of manufacturing and more particularly to a CMOS device with a stress inducing material embedded in both gates and also in the source/drain region of the PFET and varying thickness of the PFET and NFET channel. In one embodiment, the structure enhances the device performance by varying the thickness of the top Silicon layer respective to the NFET or the PFET. | 01-21-2010 |
20100112766 | SEMICONDUCTOR STRUCTURE AND METHOD OF FORMING THE STRUCTURE - Disclosed are embodiments of an n-FET structure with silicon carbon S/D regions completely contained inside amorphization regions and with a carbon-free gate electrode. Containing carbon within the amorphization regions, ensures that all of the carbon is substitutional following re-crystallization to maximize the tensile stress imparted on channel region. The gate stack is capped during carbon implantation so the risk of carbon entering the gate stack and degrading the conductivity of the gate polysilicon and/or damaging the gate oxide is essentially eliminated. Thus, the carbon implant regions can be formed deeper. Deeper S/D carbon implants which are completely amorphized and then re-crystallized provide greater tensile stress on the n-FET channel region to further optimize electron mobility. Additionally, the gate electrode is uncapped during the n-type dopant process, so the n-type dopant dose in the gate electrode can be at least great as the dose in the S/D regions. | 05-06-2010 |
20100244139 | STRAINED-SILICON CMOS DEVICE AND METHOD - The present invention provides a semiconductor device and a method of forming thereof, in which a uniaxial strain is produced in the device channel of the semiconductor device. The uniaxial strain may be in tension or in compression and is in a direction parallel to the device channel. The uniaxial strain can be produced in a biaxially strained substrate surface by strain inducing liners, strain inducing wells or a combination thereof. The uniaxial strain may be produced in a relaxed substrate by the combination of strain inducing wells and a strain inducing liner. The present invention also provides a means for increasing biaxial strain with strain inducing isolation regions. The present invention further provides CMOS devices in which the device regions of the CMOS substrate may be independently processed to provide uniaxially strained semiconducting surfaces in compression or tension. | 09-30-2010 |
20100304563 | MOSFET STRUCTURE WITH MULTIPLE SELF-ALIGNED SILICIDE CONTACTS - A metal oxide semiconductor field effect transistor (MOSFET) structure that includes multiple and distinct self-aligned silicide contacts and methods of fabricating the same are provided. The MOSFET structure includes at least one metal oxide semiconductor field effect transistor having a gate conductor including a gate edge located on a surface of a Si-containing substrate; a first inner silicide having an edge that is substantially aligned to the gate edge of the at least one metal oxide semiconductor field effect transistor; and a second outer silicide located adjacent to the first inner silicide. In accordance with the present invention, the second outer silicide has second thickness is greater than the first thickness of the first inner silicide. Moreover, the second outer silicide has a resistivity that is lower than the resistivity of the first inner silicide. | 12-02-2010 |
20110147885 | FORMATION OF IMPROVED SOI SUBSTRATES USING BULK SEMICONDUCTOR WAFERS - The present invention relates to a semiconductor-on-insulator (SOI) substrate having one or more device regions. Each device region comprises at least a base semiconductor substrate layer and a semiconductor device layer with a buried insulator layer located therebetween, while the semiconductor device layer is supported by one or more vertical insulating pillars. The vertical insulating pillars each preferably has a ledge extending between the base semiconductor substrate layer and the semiconductor device layer. The SOI substrates of the present invention can be readily formed from a precursor substrate structure with a “floating” semiconductor device layer that is spaced apart from the base semiconductor substrate layer by an air gap and is supported by one or more vertical insulating pillars. The air gap is preferably formed by selective removal of a sacrificial layer located between the base semiconductor substrate layer and the semiconductor device layer. | 06-23-2011 |
20120091506 | Method and Structure for pFET Junction Profile With SiGe Channel - A semiconductor structure including a p-channel field effect transistor (pFET) device located on a surface of a silicon germanium (SiGe) channel is provided in which the junction profile of the source region and the drain region is abrupt. The abrupt source/drain junctions for pFET devices are provided in this disclosure by forming an N- or C-doped Si layer directly beneath a SiGe channel layer which is located above a Si substrate. A structure is thus provided in which the N- or C-doped Si layer (sandwiched between the SiGe channel layer and the Si substrate) has approximately the same diffusion rate for a p-type dopant as the overlying SiGe channel layer. Since the N- or C-doped Si layer and the overlying SiGe channel layer have substantially the same diffusivity for a p-type dopant and because the N- or C-doped Si layer retards diffusion of the p-type dopant into the underlying Si substrate, abrupt source/drain junctions can be formed. | 04-19-2012 |
20120146092 | STRUCTURE AND METHOD FOR MOBILITY ENHANCED MOSFETS WITH UNALLOYED SILICIDE - While embedded silicon germanium alloy and silicon carbon alloy provide many useful applications, especially for enhancing the mobility of MOSFETs through stress engineering, formation of alloyed silicide on these surfaces degrades device performance. The present invention provides structures and methods for providing unalloyed silicide on such silicon alloy surfaces placed on semiconductor substrates. This enables the formation of low resistance contacts for both mobility enhanced PFETs with embedded SiGe and mobility enhanced NFETs with embedded Si:C on the same semiconductor substrate. Furthermore, this invention provides methods for thick epitaxial silicon alloy, especially thick epitaxial Si:C alloy, above the level of the gate dielectric to increase the stress on the channel on the transistor devices. | 06-14-2012 |
20120149159 | STRUCTURE AND METHOD FOR MOBILITY ENHANCED MOSFETS WITH UNALLOYED SILICIDE - While embedded silicon germanium alloy and silicon carbon alloy provide many useful applications, especially for enhancing the mobility of MOSFETs through stress engineering, formation of alloyed silicide on these surfaces degrades device performance. The present invention provides structures and methods for providing unalloyed silicide on such silicon alloy surfaces placed on semiconductor substrates. This enables the formation of low resistance contacts for both mobility enhanced PFETs with embedded SiGe and mobility enhanced NFETs with embedded Si:C on the same semiconductor substrate. Furthermore, this invention provides methods for thick epitaxial silicon alloy, especially thick epitaxial Si:C alloy, above the level of the gate dielectric to increase the stress on the channel on the transistor devices. | 06-14-2012 |
20140123097 | COMPACT MODEL FOR DEVICE/CIRCUIT/CHIP LEAKAGE CURRENT (IDDQ) CALCULATION INCLUDING PROCESS INDUCED UPLIFT FACTORS - A system, method and computer program product for implementing a quiescent current leakage specific model into semiconductor device design and circuit design flows. The leakage model covers all device geometries with wide temperature and voltage ranges and, without the need for stacking factor calculations nor spread sheet based IDDQ calculations. The leakage model for IDDQ calculation incorporates further parasitic and proximity effects. The leakage model implements leakage calculations at different levels of testing, e.g., from a single device to a full chip design, and are integrated within one single model. The leakage model implements leakage calculations at different levels of testing with the leverage of a single switch setting. The implementation is via a hardware definition language code or object oriented code that can be compiled and operated using a netlist of interest, e.g., for conducting a performance analysis. | 05-01-2014 |
20140124860 | METHOD AND STRUCTURE FOR FORMING A LOCALIZED SOI FINFET - Methods and structures for forming a localized silicon-on-insulator (SOI) finFET are disclosed. Fins are formed on a bulk substrate. Nitride spacers protect the fin sidewalls. A shallow trench isolation region is deposited over the fins. An oxidation process causes oxygen to diffuse through the shallow trench isolation region and into the underlying silicon. The oxygen reacts with the silicon to form oxide, which provides electrical isolation for the fins. The shallow trench isolation region is in direct physical contact with the fins and/or the nitride spacers that are disposed on the fins. | 05-08-2014 |
20140124863 | METHOD AND STRUCTURE FOR FORMING A LOCALIZED SOI FINFET - Methods and structures for forming a localized silicon-on-insulator (SOI) finFET are disclosed. Fins are formed on a bulk substrate. Nitride spacers protect the fin sidewalls. A shallow trench isolation region is deposited over the fins. An oxidation process causes oxygen to diffuse through the shallow trench isolation region and into the underlying silicon. The oxygen reacts with the silicon to form oxide, which provides electrical isolation for the fins. The shallow trench isolation region is in direct physical contact with the fins and/or the nitride spacers that are disposed on the fins. Structures comprising bulk-type fins, SOI-type fins, and planar regions are also disclosed. | 05-08-2014 |
20140191297 | STRAINED FINFET WITH AN ELECTRICALLY ISOLATED CHANNEL - A fin structure includes an optional doped well, a disposable single crystalline semiconductor material portion, and a top semiconductor portion formed on a substrate. A disposable gate structure straddling the fin structure is formed, and end portions of the fin structure are removed to form end cavities. Doped semiconductor material portions are formed on sides of a stack of the disposable single crystalline semiconductor material portion and a channel region including the top semiconductor portion. The disposable single crystalline semiconductor material portion may be replaced with a dielectric material portion after removal of the disposable gate structure or after formation of the stack. The gate cavity is filled with a gate dielectric and a gate electrode. The channel region is stressed by the doped semiconductor material portions, and is electrically isolated from the substrate by the dielectric material portion. | 07-10-2014 |
20140266254 | Techniques for Quantifying Fin-Thickness Variation in FINFET Technology - Techniques for quantifying ΔDfin in FINFET technology are provided. In one aspect, a method for quantifying ΔDfin between a pair of long channel FINFET devices includes the steps of: (a) obtaining Vth values for each of the long channel FINFET devices in the pair; (b) determining a ΔVth for the pair of long channel FINFET devices; and (c) using the ΔVth to determine the ΔDfin between the pair of long channel FINFET devices, wherein the ΔVth is a function of a difference in a Qbody and a gate capacitance between the pair of long channel FINFET devices, and wherein the Qbody is a function of Dfin and Nch for each of the long channel FINFET devices in the pair, and as such the ΔVth is proportional to the ΔDfin between the pair of long channel FINFET devices. | 09-18-2014 |
20140273298 | Techniques for Quantifying Fin-Thickness Variation in FINFET Technology - Techniques for quantifying ΔDfin in FINFET technology are provided. In one aspect, a method for quantifying ΔDfin between a pair of long channel FINFET devices includes the steps of: (a) obtaining Vth values for each of the long channel FINFET devices in the pair; (b) determining a ΔVth for the pair of long channel FINFET devices; and (c) using the ΔVth to determine the ΔDfin between the pair of long channel FINFET devices, wherein the ΔVth is a function of a difference in a Qbody and a gate capacitance between the pair of long channel FINFET devices, and wherein the Qbody is a function of Dfin and Nch for each of the long channel FINFET devices in the pair, and as such the ΔVth is proportional to the ΔDfin between the pair of long channel FINFET devices. | 09-18-2014 |
20140273381 | METHOD AND STRUCTURE FOR pFET JUNCTION PROFILE WITH SiGe CHANNEL - A semiconductor structure including a p-channel field effect transistor (pFET) device located on a surface of a silicon germanium (SiGe) channel is provided in which the junction profile of the source/drain region is abrupt. The abrupt source/drain junctions for pFET devices are provided by forming an N- or C-doped Si layer directly beneath a SiGe channel layer which is located above a Si substrate. A structure is provided in which the N- or C-doped Si layer (sandwiched between the SiGe channel layer and the Si substrate) has approximately the same diffusion rate for a p-type dopant as the overlying SiGe channel layer. Since the N- or C-doped Si layer and the overlying SiGe channel layer have substantially the same diffusivity for a p-type dopant and because the N- or C-doped Si layer retards diffusion of the p-type dopant into the underlying Si substrate, abrupt source/drain junctions can be formed. | 09-18-2014 |
20140332861 | FIN STRUCTURE WITH VARYING ISOLATION THICKNESS - Semiconductor fins having isolation regions of different thicknesses on the same integrated circuit are disclosed. Nitride spacers protect the lower portion of some fins, while other fins do not have spacers on the lower portion. The exposed lower portion of the fins are oxidized to provide isolation regions of different thicknesses. | 11-13-2014 |
20140377924 | STRAINED FINFET WITH AN ELECTRICALLY ISOLATED CHANNEL - A fin structure includes an optional doped well, a disposable single crystalline semiconductor material portion, and a top semiconductor portion formed on a substrate. A disposable gate structure straddling the fin structure is formed, and end portions of the fin structure are removed to form end cavities. Doped semiconductor material portions are formed on sides of a stack of the disposable single crystalline semiconductor material portion and a channel region including the top semiconductor portion. The disposable single crystalline semiconductor material portion may be replaced with a dielectric material portion after removal of the disposable gate structure or after formation of the stack. The gate cavity is filled with a gate dielectric and a gate electrode. The channel region is stressed by the doped semiconductor material portions, and is electrically isolated from the substrate by the dielectric material portion. | 12-25-2014 |
20150028398 | DIELECTRIC FILLER FINS FOR PLANAR TOPOGRAPHY IN GATE LEVEL - An array of stacks containing a semiconductor fins and an oxygen-impermeable cap is formed on a semiconductor substrate with a substantially uniform areal density. Oxygen-impermeable spacers are formed around each stack, and the semiconductor substrate is etched to vertically extend trenches. Semiconductor sidewalls are physically exposed from underneath the oxygen-impermeable spacers. The oxygen-impermeable spacers are removed in regions in which semiconductor fins are not needed. A dielectric oxide material is deposited to fill the trenches. Oxidation is performed to convert a top portion of the semiconductor substrate and semiconductor fins not protected by oxygen-impermeable spacers into dielectric material portions. Upon removal of the oxygen-impermeable caps and remaining oxygen-impermeable spacers, an array including semiconductor fins and dielectric fins is provided. The dielectric fins alleviate variations in the local density of protruding structures, thereby reducing topographical variations in the height of gate level structures to be subsequently formed. | 01-29-2015 |
20150028419 | FIN FIELD EFFECT TRANSISTOR WITH DIELECTRIC ISOLATION AND ANCHORED STRESSOR ELEMENTS - A first fin field effect transistor and a second fin field effect transistor are formed on an insulator layer overlying a semiconductor material layer. A first pair of trenches is formed through the insulator layer in regions in which a source region and a drain region of the first fin field effect transistor is to be formed. A second pair of trenches is formed partly into the insulator layer without extending to the top surface of the semiconductor material layer. The source region and the drain region of the first field effect transistor can be epitaxial stressor material portions that are anchored to, and epitaxially aligned to, the semiconductor material layer and apply stress to the channel of the first field effect transistor to enhance performance. The insulator layer provides electrical isolation from the semiconductor material layer to the second field effect transistor. | 01-29-2015 |