Patent application number | Description | Published |
20080237709 | AFTER GATE FABRICATION OF FIELD EFFECT TRANSISTOR HAVING TENSILE AND COMPRESSIVE REGIONS - A field effect transistor (“FET”) is formed to include a stress in a channel region of an active semiconductor region of an SOI substrate. A gate is formed to overlie the active semiconductor region, after which a sacrificial stressed layer is formed which overlies the gate and the active semiconductor region. Then, the SOI substrate is heated to cause a flowable dielectric material in a buried dielectric layer of the SOI substrate to soften and reflow. As a result of the reflowing, the sacrificial stressed layer induces stress in a channel region of the active semiconductor region underlying the gate. A source region and a drain region are formed in the active semiconductor region, desirably after removing the sacrificial stressed layer. | 10-02-2008 |
20080258234 | SEMICONDUCTOR STRUCTURE FOR LOW PARASITIC GATE CAPACITANCE - A semiconductor structure provides lower parasitic capacitance between the gate electrode and contact vias while providing substantially the same level of stress applied by a nitride liner as conventional MOSFETs by reducing the height of the gate electrode and maintaining substantially the same height for the gate spacer. The nitride liner contacts only the outer sidewalls of the gate spacer, while not contacting inner sidewalls, or only a small area of the inner sidewalls of the gate spacer, therefore applying substantially the same level of stress to the channel of the MOSFET as conventional MOSFETs. The volume surrounded by the gate spacer and located above the gate electrode is either filled with a low-k dielectric material or occupied by a cavity having a dielectric constant of substantially 1.0. The reduced height of the gate electrode and the low-k dielectric gate filler or the cavity reduces the parasitic capacitance. | 10-23-2008 |
20080280404 | RESIDUE FREE PATTERNED LAYER FORMATION METHOD APPLICABLE TO CMOS STRUCTURES - A method for forming a microelectronic structure uses a mask layer located over a target layer. The target layer may be etched while using the mask layer as an etch mask to form an end tapered target layer from the target layer. An additional target layer may be formed over the end tapered target layer and masked with an additional mask layer. The additional target layer may be etched to form a patterned additional target layer separated from the end tapered target layer and absent an additional target layer residue adjacent the end tapered target layer. The method is useful for fabricating CMOS structures including nFET and pFET gate electrodes comprising different NFET and pFET gate electrode materials. | 11-13-2008 |
20090040006 | ELECTRICAL FUSE WITH ENHANCED PROGRAMMING CURRENT DIVERGENCE - A layer of semiconductor material is patterned to form a cathode semiconductor portion, a fuselink semiconductor portion, and an anode semiconductor portion. A first metal layer is deposited on the patterned semiconductor material layer. A dielectric material layer is deposited and lithographically patterned to cover a middle portion of the fuselink, followed by a deposition of a second metal layer. A thin metal semiconductor alloy is formed in the middle of the fuselink and thick metal semiconductor alloy alloys are formed abutting the thin metal semiconductor alloy alloy. The resulting inventive electrical fuse has interfaces at which a thinner metal semiconductor alloy abuts a thicker metal semiconductor alloy in the fuselink. The divergence of electrical current is enhanced at the interfaces due to a sudden change of a cross-sectional area available for current conduction. | 02-12-2009 |
20090042341 | ELECTRICAL FUSE WITH A THINNED FUSELINK MIDDLE PORTION - A metal layer is deposited on the patterned semiconductor material layer containing a cathode semiconductor portion, a fuselink semiconductor portion, and an anode semiconductor portion. The metal layer may be patterned so that a middle portion of the fuselink semiconductor portion has a thin metal layer, which upon annealing produces a thinner metal semiconductor alloy portion than surrounding metal semiconductor alloy portion on the fuselink semiconductor portion. Alternatively, a middle portion of the metal semiconductor alloy having a uniform thickness throughout the fuselink may be lithographically patterned and etched to form a thin metal semiconductor alloy portion in the middle of the fuselink, while thick metal semiconductor alloy portions are formed on the end portions of the fuselink. The resulting inventive electrical fuse has interfaces at which a thinner metal semiconductor alloy abuts a thicker metal semiconductor alloy in the fuselink to enhance the divergence of electrical current. | 02-12-2009 |
20090090977 | RESISTOR AND FET FORMED FROM THE METAL PORTION OF A MOSFET METAL GATE STACK - An integrated semiconductor device includes a resistor and an FET device formed from a stack of layers. The stack of layers includes a dielectric layer formed on a substrate; a metal conductor layer having lower electrical resistance formed on the dielectric layer; and a polysilicon layer formed on the metal conductor layer. A resistor stack is formed by patterning a portion of the original stack of layers into a resistor. An FET stack is formed from another portion of the original stack of layers. The FET stack is doped to form a gate electrode and the resistor stack is doped aside from the resistor portion thereof. Then terminals are formed at distal ends of the resistor in a doped portion of the polysilicon layer. Alternatively, the polysilicon layer is etched away from the resistor stack followed by forming terminals at distal ends of the metal conductor in the resistor stack. | 04-09-2009 |
20090090993 | SINGLE CRYSTAL FUSE ON AIR IN BULK SILICON - An integrated eFUSE device is formed by forming a silicon “floating beam” on air, whereupon the fusible portion of the eFUSE device resides. This beam extends between two larger, supporting terminal structures. “Undercutting” techniques are employed whereby a structure is formed atop a buried layer, and that buried layer is removed by selective etching. Whereby a “floating” silicide eFUSE conductor is formed on a silicon beam structure. In its initial state, the eFUSE silicide is highly conductive, exhibiting low electrical resistance (the “unblown state of the eFUSE). When a sufficiently large current is passed through the eFUSE conductor, localized heating occurs. This heating causes electromigration of the silicide into the silicon beam (and into surrounding silicon, thereby diffusing the silicide and greatly increasing its electrical resistance. When the current source is removed, the silicide remains permanently in this diffused state, the “blown” state of the eFUSE. | 04-09-2009 |
20090108396 | ELECTRICAL FUSE HAVING A FULLY SILICIDED FUSELINK AND ENHANCED FLUX DIVERGENCE - A contiguous block of a stack of two heterogeneous semiconductor layers is formed over an insulator region such as shallow trench isolation. A portion of the contiguous block is exposed to an etch, while another portion is masked during the etch. The etch removes an upper semiconductor layer selective to a lower semiconductor layer in the exposed portion. The etch mask is removed and the entirety of the lower semiconductor layer within the exposed region is metallized. A first metal semiconductor alloy vertically abutting the insulator region is formed, while exposed surfaces of the stack of two heterogeneous semiconductor layers, which comprises the materials of the upper semiconductor layer, are concurrently metallized to form a second metal semiconductor alloy. An inflection point for current and, consequently, a region of flux divergence are formed at the boundary of the two metal semiconductor alloys. | 04-30-2009 |
20090152650 | HIGH-K DIELECTRIC AND METAL GATE STACK WITH MINIMAL OVERLAP WITH ISOLATION REGION AND RELATED METHODS - A high-k dielectric and metal gate stack with minimal overlap with an adjacent oxide isolation region and related methods are disclosed. One embodiment of the gate stack includes a high dielectric constant (high-k) dielectric layer, a tuning layer and a metal layer positioned over an active region defined by an oxide isolation region in a substrate, wherein an outer edge of the high-k dielectric layer, the tuning layer and the metal layer overlaps the oxide isolation region by less than approximately 200 nanometers. The gate stack and related methods eliminate the regrowth effect in short channel devices by restricting the amount of overlap area between the gate stack and adjacent oxide isolation regions. | 06-18-2009 |
20090186455 | DISPOSABLE METALLIC OR SEMICONDUCTOR GATE SPACER - A disposable spacer is formed directly on or in close proximity to the sidewalls of a gate electrode and a gate dielectric. The disposable spacer comprises a material that scavenges oxygen such as a metal, a metal nitride, or a semiconductor material having high reactivity with oxygen. The disposable gate spacer absorbs any oxygen during subsequent high temperature processing such as a stress memorization anneal. A metal is deposited over, and reacted with, the gate electrode and source and drain regions to form metal semiconductor alloy regions. The disposable gate spacer is subsequently removed selective to the metal semiconductor alloy regions. A porous or non-porous low-k dielectric material is deposited to provide a low parasitic capacitance between the gate electrode and the source and drain regions. The gate dielectric maintains the original dielectric constant since the disposable gate spacer prevents absorption of additional oxygen during high temperature processes. | 07-23-2009 |
20090194820 | CMOS (COMPLEMENTARY METAL OXIDE SEMICONDUCTOR) DEVICES HAVING METAL GATE NFETS AND POLY-SILICON GATE PFETS - A semiconductor structure fabrication method. The method includes providing a structure which includes (a) first and second semiconductor regions, (b) first and second gate dielectric regions on the first and second semiconductor regions, respectively, (c) a high-K dielectric region on the first gate dielectric region, K being greater than 4, (d) an electrically conductive layer on the high-K dielectric region, (e) a poly-silicon layer on the electrically conductive layer and the second gate dielectric region, and (f) a hard mask layer on the poly-silicon layer. The hard mask layer is patterned resulting in first and second hard mask regions. The poly-silicon layer is etched with the first and second hard mask regions as blocking masks resulting in first and second poly-silicon regions. The first and second poly-silicon regions are exposed to a surrounding ambient. | 08-06-2009 |
20090250760 | METHODS OF FORMING HIGH-K/METAL GATES FOR NFETS AND PFETS - Methods of forming high-k/metal gates for an NFET and PFET and a related structure are disclosed. One method includes recessing a PFET region; forming a first high-k dielectric layer and a first metal layer over the substrate; removing the first high-k dielectric layer and the first metal over the NFET region using a mask; forming a forming a second high-k dielectric layer and a second metal layer over the substrate, the first high-k dielectric layer being different then the second high-k dielectric layer and the first metal being different than the second metal; removing the second high-k dielectric layer and the second metal over the PFET region using a mask; depositing a polysilicon over the substrate; and forming a gate over the NFET region and the PFET region by simultaneously etching the polysilicon, the first high-k dielectric layer, the first metal, the second high-k dielectric layer and the second metal. | 10-08-2009 |
20090256207 | FINFET DEVICES FROM BULK SEMICONDUCTOR AND METHODS FOR MANUFACTURING THE SAME - Disclosed herein is a transistor comprising a first fin having a first gate electrode disposed across the first fin; the gate electrode contacting opposing surfaces of the fin; and a planar oxide layer having a second gate electrode disposed across the planar oxide layer to form a planar metal oxide semiconductor field effect transistor; the first fin and the planar oxide layer being disposed upon a surface of a wafer. | 10-15-2009 |
20100181643 | EFUSE WITH PARTIAL SIGE LAYER AND DESIGN STRUCTURE THEREFOR - A fuse includes a fuse link region, a first region and a second region. The fuse link region electrically connects the first region to the second region. A SiGe layer is disposed only in the fuse link region and the first region. | 07-22-2010 |
20100187610 | SEMICONDUCTOR DEVICE HAVING DUAL METAL GATES AND METHOD OF MANUFACTURE - A semiconductor device includes: a semiconductor substrate; a PFET formed on the substrate, the PFET includes a SiGe layer disposed on the substrate, a high-K dielectric layer disposed on the SiGe layer, a first metallic layer disposed on the high-k dielectric layer, a first intermediate layer disposed on the first metallic layer, a second metallic layer disposed on the first intermediate layer, a second intermediate layer disposed on the second metallic layer, and a third metallic layer disposed on the second intermediate layer; an NFET formed on the substrate, the NFET includes the high-k dielectric layer, the high-k dielectric layer being disposed on the substrate, the second intermediate layer, the second intermediate layer being disposed on the high-k dielectric layer, and the third metallic layer, the third metallic layer being disposed on the second intermediate layer. Alternatively, the first metallic layer is omitted. A method to fabricate the device includes providing SiO | 07-29-2010 |
20100237435 | METHOD AND STRUCTURE FOR GATE HEIGHT SCALING WITH HIGH-K/METAL GATE TECHNOLOGY - A method and structure to scale metal gate height in high-k/metal gate transistors. A method includes forming a dummy gate and at least one polysilicon feature, all of which are formed from a same polysilicon layer and wherein the dummy gate is formed over a gate metal layer associated with a transistor. The method also includes selectively removing the dummy gate while protecting the at least one polysilicon feature. The method further includes forming a gate contact on the gate metal layer to thereby form a metal gate having a height that is less than half a height of the at least one polysilicon feature. | 09-23-2010 |
20100258875 | CMOS (COMPLEMENTARY METAL OXIDE SEMICONDUCTOR) DEVICES HAVING METAL GATE NFETS AND POLY-SILICON GATE PFETS - A semiconductor structure. The semiconductor structure includes: a first semiconductor region and a second semiconductor region; a first gate dielectric region on the first semiconductor region; a second gate dielectric region on the second semiconductor region, wherein the second semiconductor region includes a first top surface shared by the second semiconductor region and the second gate dielectric region, and wherein the first top surface defines a reference direction perpendicular to the first top surface and pointing from inside to outside of the second semiconductor region; an electrically conductive layer on the first gate dielectric region; a first poly-silicon region on the electrically conductive layer; a second poly-silicon region on the second gate dielectric region; a first hard mask region on the first poly-silicon region; and a second hard mask region on the second poly-silicon region. | 10-14-2010 |
20100264495 | High-K Metal Gate CMOS - A method of forming a semiconductor device is provided that includes forming a Ge-containing layer atop a p-type device regions of the substrate. Thereafter, a first dielectric layer is formed in a second portion of a substrate, and a second dielectric layer is formed overlying the first dielectric layer in the second portion of the substrate and overlying a first portion of the substrate. Gate structures may then formed atop the p-type device regions and n-type device regions of the substrate, in which the gate structures to the n-type device regions include a rare earth metal. | 10-21-2010 |
20100276753 | Threshold Voltage Adjustment Through Gate Dielectric Stack Modification - Multiple types of gate stacks are formed on a doped semiconductor well. A high dielectric constant (high-k) gate dielectric is formed on the doped semiconductor well. A metal gate layer is formed in one device area, while the high-k gate dielectric is exposed in other device areas. Threshold voltage adjustment oxide layers having different thicknesses are formed in the other device areas. A conductive gate material layer is then formed over the threshold voltage adjustment oxide layers. One type of field effect transistors includes a gate dielectric including a high-k gate dielectric portion. Other types of field effect transistors include a gate dielectric including a high-k gate dielectric portion and a first threshold voltage adjustment oxide portions having different thicknesses. Field effect transistors having different threshold voltages are provided by employing different gate dielectric stacks and doped semiconductor wells having the same dopant concentration. | 11-04-2010 |
20100330783 | ELECTRICAL FUSE HAVING A FULLY SILICIDED FUSELINK AND ENHANCED FLUX DIVERGENCE - A contiguous block of a stack of two heterogeneous semiconductor layers is formed over an insulator region such as shallow trench isolation. A portion of the contiguous block is exposed to an etch, while another portion is masked during the etch. The etch removes an upper semiconductor layer selective to a lower semiconductor layer in the exposed portion. The etch mask is removed and the entirety of the lower semiconductor layer within the exposed region is metallized. A first metal semiconductor alloy vertically abutting the insulator region is formed, while exposed surfaces of the stack of two heterogeneous semiconductor layers, which comprises the materials of the upper semiconductor layer, are concurrently metallized to form a second metal semiconductor alloy. An inflection point for current and, consequently, a region of flux divergence are formed at the boundary of the two metal semiconductor alloys. | 12-30-2010 |
20110156158 | HIGH-K METAL GATE CMOS - A method of forming a semiconductor device is provided that includes forming a Ge-containing layer atop a p-type device regions of the substrate. Thereafter, a first dielectric layer is formed in a second portion of a substrate, and a second dielectric layer is formed overlying the first dielectric layer in the second portion of the substrate and overlying a first portion of the substrate. Gate structures may then formed atop the p-type device regions and n-type device regions of the substrate, in which the gate structures to the n-type device regions include a rare earth metal. | 06-30-2011 |
20110221012 | HIGH-K DIELECTRIC GATE STRUCTURES RESISTANT TO OXIDE GROWTH AT THE DIELECTRIC/SILICON SUBSTRATE INTERFACE AND METHODS OF MANUFACTURE THEREOF - Methods for fabricating gate electrode/high-k dielectric gate structures having an improved resistance to the growth of silicon dioxide (oxide) at the dielectric/silicon-based substrate interface. In an embodiment, a method of forming a transistor gate structure comprises: incorporating nitrogen into a silicon-based substrate proximate a surface of the substrate; depositing a high-k gate dielectric across the silicon-based substrate; and depositing a gate electrode across the high-k dielectric to form the gate structure. In one embodiment, the gate electrode comprises titanium nitride rich in titanium for inhibiting diffusion of oxygen. | 09-15-2011 |
20110227171 | HIGH-K DIELECTRIC AND METAL GATE STACK WITH MINIMAL OVERLAP WITH ISOLATION REGION - A high-k dielectric and metal gate stack with minimal overlap with an adjacent oxide isolation region and related methods are disclosed. One embodiment of the gate stack includes a high dielectric constant (high-k) dielectric layer, a tuning layer and a metal layer positioned over an active region defined by an oxide isolation region in a substrate, wherein an outer edge of the high-k dielectric layer, the tuning layer and the metal layer overlaps the oxide isolation region by less than approximately 200 nanometers. The gate stack and related methods eliminate the regrowth effect in short channel devices by restricting the amount of overlap area between the gate stack and adjacent oxide isolation regions. | 09-22-2011 |
20110248350 | METHOD AND STRUCTURE FOR WORK FUNCTION ENGINEERING IN TRANSISTORS INCLUDING A HIGH DIELECTRIC CONSTANT GATE INSULATOR AND METAL GATE (HKMG) - Adjustment of a switching threshold of a field effect transistor including a gate structure including a Hi-K gate dielectric and a metal gate is achieved and switching thresholds coordinated between NFETs and PFETs by providing fixed charge materials in a thin interfacial layer adjacent to the conduction channel of the transistor that is provided for adhesion of the Hi-K material, preferably hafnium oxide or HfSiON, depending on design, to semiconductor material rather than diffusing fixed charge material into the Hi-K material after it has been applied. The greater proximity of the fixed charge material to the conduction channel of the transistor increases the effectiveness of fixed charge material to adjust the threshold due to the work function of the metal gate, particularly where the same metal or alloy is used for both NFETs and PFETs in an integrated circuit; preventing the thresholds from being properly coordinated. | 10-13-2011 |
20110298008 | SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME - A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions. | 12-08-2011 |
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 |
20120104505 | STRUCTURE AND METHOD FOR USING HIGH-K MATERIAL AS AN ETCH STOP LAYER IN DUAL STRESS LAYER PROCESS - A method is provided that includes forming a high-k dielectric etch stop layer over at least a first conductivity type semiconductor device on a first portion of a substrate and at least a second conductivity type semiconductor device on a second portion of the semiconductor device. A first stress-inducing layer is deposited over the first conductivity type semiconductor device and the second conductivity type semiconductor device. The portion of the first stress-inducing layer that is formed over the second conductivity type semiconductor device is then removed with an etch that is selective to the high-k dielectric etch stop layer to provide an exposed surface of second portion of the substrates that includes at least the second conductivity type semiconductor device. A second stress-inducing layer is then formed over the second conductivity type semiconductor device. | 05-03-2012 |
20120108017 | THRESHOLD VOLTAGE ADJUSTMENT THROUGH GATE DIELECTRIC STACK MODIFICATION - Multiple types of gate stacks are formed on a doped semiconductor well. A high dielectric constant (high-k) gate dielectric is formed on the doped semiconductor well. A metal gate layer is formed in one device area, while the high-k gate dielectric is exposed in other device areas. Threshold voltage adjustment oxide layers having different thicknesses are formed in the other device areas. A conductive gate material layer is then formed over the threshold voltage adjustment oxide layers. One type of field effect transistors includes a gate dielectric including a high-k gate dielectric portion. Other types of field effect transistors include a gate dielectric including a high-k gate dielectric portion and a first threshold voltage adjustment oxide portions having different thicknesses. Field effect transistors having different threshold voltages are provided by employing different gate dielectric stacks and doped semiconductor wells having the same dopant concentration. | 05-03-2012 |
20120126335 | METHOD AND STRUCTURE FOR GATE HEIGHT SCALING WITH HIGH-K/METAL GATE TECHNOLOGY - A method and structure to scale metal gate height in high-k/metal gate transistors. A method includes forming a dummy gate and at least one polysilicon feature, all of which are formed from a same polysilicon layer and wherein the dummy gate is formed over a gate metal layer associated with a transistor. The method also includes selectively removing the dummy gate while protecting the at least one polysilicon feature. The method further includes forming a gate contact on the gate metal layer to thereby form a metal gate having a height that is less than half a height of the at least one polysilicon feature. | 05-24-2012 |
20120208337 | SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME - A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions. | 08-16-2012 |
20120214299 | METHOD AND STRUCTURE FOR WORK FUNCTION ENGINEERING IN TRANSISTORS INCLUDING A HIGH DIELECTRIC CONSTANT GATE INSULATOR AND METAL GATE (HKMG) - Adjustment of a switching threshold of a field effect transistor including a gate structure including a Hi-K gate dielectric and a metal gate is achieved and switching thresholds coordinated between NFETs and PFETs by providing fixed charge materials in a thin interfacial layer adjacent to the conduction channel of the transistor that is provided for adhesion of the Hi-K material, preferably hafnium oxide or HfSiON, depending on design, to semiconductor material rather than diffusing fixed charge material into the Hi-K material after it has been applied. The greater proximity of the fixed charge material to the conduction channel of the transistor increases the effectiveness of fixed charge material to adjust the threshold due to the work function of the metal gate, particularly where the same metal or alloy is used for both NFETs and PFETs in an integrated circuit; preventing the thresholds from being properly coordinated. | 08-23-2012 |
20120286374 | HIGH-K DIELECTRIC GATE STRUCTURES RESISTANT TO OXIDE GROWTH AT THE DIELECTRIC/SILICON SUBSTRATE INTERFACE AND METHODS OF MANUFACTURE THEREOF - Methods for fabricating gate electrode/high-k dielectric gate structures having an improved resistance to the growth of silicon dioxide (oxide) at the dielectric/silicon-based substrate interface. In an embodiment, a method of forming a transistor gate structure comprises: incorporating nitrogen into a silicon-based substrate proximate a surface of the substrate; depositing a high-k gate dielectric across the silicon-based substrate; and depositing a gate electrode across the high-k dielectric to form the gate structure. In one embodiment, the gate electrode comprises titanium nitride rich in titanium for inhibiting diffusion of oxygen. | 11-15-2012 |
20130087859 | Work Function Adjustment By Carbon Implant In Semiconductor Devices Including Gate Structure - A device including a p-type semiconductor device and an n-type semiconductor device on a semiconductor substrate. The n-type semiconductor device includes a gate structure having a high-k gate dielectric. A carbon dopant in a concentration ranging from 1×10 | 04-11-2013 |
20130105894 | THRESHOLD VOLTAGE ADJUSTMENT FOR THIN BODY MOSFETS | 05-02-2013 |
20130105896 | Threshold Voltage Adjustment For Thin Body Mosfets | 05-02-2013 |
20130168776 | Complementary Metal Oxide Semiconductor (CMOS) Device Having Gate Structures Connected By A Metal Gate Conductor - A complementary metal oxide semiconductor (CMOS) device including a substrate including a first active region and a second active region, wherein each of the first active region and second active region of the substrate are separated by from one another by an isolation region. A n-type semiconductor device is present on the first active region of the substrate, in which the n-type semiconductor device includes a first portion of a gate structure. A p-type semiconductor device is present on the second active region of the substrate, in which the p-type semiconductor device includes a second portion of the gate structure. A connecting gate portion provides electrical connectivity between the first portion of the gate structure and the second portion of the gate structure. Electrical contact to the connecting gate portion is over the isolation region, and is not over the first active region and/or the second active region. | 07-04-2013 |
20130175634 | STRUCTURE AND METHOD FOR USING HIGH-K MATERIAL AS AN ETCH STOP LAYER IN DUAL STRESS LAYER PROCESS - A method is provided that includes forming a high-k dielectric etch stop layer over at least a first conductivity type semiconductor device on a first portion of a substrate and at least a second conductivity type semiconductor device on a second portion of the semiconductor device. A first stress-inducing layer is deposited over the first conductivity type semiconductor device and the second conductivity type semiconductor device. The portion of the first stress-inducing layer that is formed over the second conductivity type semiconductor device is then removed with an etch that is selective to the high-k dielectric etch stop layer to provide an exposed surface of second portion of the substrates that includes at least the second conductivity type semiconductor device. A second stress-inducing layer is then formed over the second conductivity type semiconductor device. | 07-11-2013 |
20140246727 | WORK FUNCTION ADJUSTMENT BY CARBON IMPLANT IN SEMICONDUCTOR DEVICES INCLUDING GATE STRUCTURE - A device including a p-type semiconductor device and an n-type semiconductor device on a semiconductor substrate. The n-type semiconductor device includes a gate structure having a high-k gate dielectric. A carbon dopant in a concentration ranging from 1×10 | 09-04-2014 |
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 |
20140349451 | COMPLEMENTARY METAL OXIDE SEMICONDUCTOR (CMOS) DEVICE HAVING GATE STRUCTURES CONNECTED BY A METAL GATE CONDUCTOR - A complementary metal oxide semiconductor (CMOS) device including a substrate including a first active region and a second active region, wherein each of the first active region and second active region of the substrate are separated by from one another by an isolation region. A n-type semiconductor device is present on the first active region of the substrate, in which the n-type semiconductor device includes a first portion of a gate structure. A p-type semiconductor device is present on the second active region of the substrate, in which the p-type semiconductor device includes a second portion of the gate structure. A connecting gate portion provides electrical connectivity between the first portion of the gate structure and the second portion of the gate structure. Electrical contact to the connecting gate portion is over the isolation region, and is not over the first active region and/or the second active region. | 11-27-2014 |