Patent application number | Description | Published |
20090078997 | DUAL METAL GATE FINFETS WITH SINGLE OR DUAL HIGH-K GATE DIELECTRIC - A first high-k gate dielectric layer and a first metal gate layer are formed on first and second semiconductor fins. A first metal gate ring is formed on the first semiconductor fin. In one embodiment, the first high-k gate dielectric layer remains on the second semiconductor fin. A second metal gate layer and a silicon containing layer are deposited and patterned to form gate electrodes. In another embodiment, a second high-k dielectric layer replaces the first high-k dielectric layer over the second semiconductor fin, followed by formation of a second metal gate layer. A first electrode comprising a first gate dielectric and a first metal gate is formed on the first semiconductor fin, while a second electrode comprising a second gate dielectric and a second metal gate is formed on the second semiconductor fin. Absence of high-k gate dielectric materials on a gate wiring prevents increase in parasitic resistance. | 03-26-2009 |
20090079026 | STRESS-GENERATING STRUCTURE FOR SEMICONDUCTOR-ON-INSULATOR DEVICES - A stack pad layers including a first pad oxide layer, a pad nitride layer, and a second pad oxide layer are formed on a semiconductor-on-insulator (SOI) substrate. A deep trench extending below a top surface or a bottom surface of a buried insulator layer of the SOI substrate and enclosing at least one top semiconductor region is formed by lithographic methods and etching. A stress-generating insulator material is deposited in the deep trench and recessed below a top surface of the SOI substrate to form a stress-generating buried insulator plug in the deep trench. A silicon oxide material is deposited in the deep trench, planarized, and recessed. The stack of pad layer is removed to expose substantially coplanar top surfaces of the top semiconductor layer and of silicon oxide plugs. The stress-generating buried insulator plug encloses, and generates a stress to, the at least one top semiconductor region. | 03-26-2009 |
20090121295 | METHOD AND STRUCTURE FOR REDUCING INDUCED MECHANICAL STRESSES - Methods and structures for relieving stresses in stressed semiconductor liners. A stress liner that enhances performance of either an NFET or a PFET is deposited over a semiconductor to cover the NFET and PFET. A disposable layer is deposited to entirely cover the stress liner, NFET and PFET. This disposable layer is selectively recessed to expose only the single stress liner over a gate of the NFET or PFET that is not enhanced by such stress liner, and then this exposed liner is removed to expose a top of such gate. Remaining portions of the disposable layer are removed, thereby enhancing performance of either the NFET or PFET, while avoiding degradation of the NFET or PFET not enhanced by the stress liner. The single stress liner is a tensile stress liner for enhancing performance of the NFET, or it is a compressive stress liner for enhancing performance of the PFET. | 05-14-2009 |
20090176350 | INTEGRATION OF ION GETTERING MATERIAL IN DIELECTRIC - A method embodiment deposits a first dielectric layer over a transistor and then implants a gettering agent into the first dielectric layer. After this first dielectric layer is formed, the method forms a second (thicker) dielectric layer over the first dielectric layer. After this, the standard contacts are formed through the insulating layer to the source, drain, gate, etc. of the transistor. Additionally, reactive ion etching, chemical mechanical processing, and other back-end-of-line processing are performed. The back-end-of-line processes can introduce mobile ions into the dielectric over a transistor; however, the gettering agent traps the mobile ions and prevents the mobile ions from contaminating the transistor. | 07-09-2009 |
20090184378 | STRUCTURE AND METHOD TO FABRICATE MOSFET WITH SHORT GATE - A method of producing a semiconducting device is provided that in one embodiment includes providing a semiconducting device including a gate structure atop a substrate, the gate structure including a dual gate conductor including an upper gate conductor and a lower gate conductor, wherein at least the lower gate conductor includes a silicon containing material; removing the upper gate conductor selective to the lower gate conductor; depositing a metal on at least the lower gate conductor; and producing a silicide from the metal and the lower gate conductor. In another embodiment, the inventive method includes a metal as the lower gate conductor. | 07-23-2009 |
20090236640 | METHOD AND STRUCTURE FOR REDUCING INDUCED MECHANICAL STRESSES - Methods and structures for relieving stresses in stressed semiconductor liners. A stress liner that enhances performance of either an NFET or a PFET is deposited over a semiconductor to cover the NFET and PFET. A disposable layer is deposited to entirely cover the stress liner, NFET and PFET. This disposable layer is selectively recessed to expose only the single stress liner over a gate of the NFET or PFET that is not enhanced by such stress liner, and then this exposed liner is removed to expose a top of such gate. Remaining portions of the disposable layer are removed, thereby enhancing performance of either the NFET or PFET, while avoiding degradation of the NFET or PFET not enhanced by the stress liner. The single stress liner is a tensile stress liner for enhancing performance of the NFET, or it is a compressive stress liner for enhancing performance of the PFET. | 09-24-2009 |
20090236676 | STRUCTURE AND METHOD TO MAKE HIGH PERFORMANCE MOSFET WITH FULLY SILICIDED GATE - The present invention in one embodiment provides a method of producing a device including providing a semiconducting device including a gate structure including a silicon containing gate conductor atop a substrate; forming a metal layer on at least the silicon containing gate conductor; and directing chemically inert ions to impact the metal layer, wherein momentum transfer from of the chemically inert ions force metal atoms from the metal layer into the silicon containing gate conductor to provide a silicide gate conductor. | 09-24-2009 |
20100006926 | METHODS FOR FORMING HIGH PERFORMANCE GATES AND STRUCTURES THEREOF - Methods for forming high performance gates in MOSFETs and structures thereof are disclosed. One embodiment includes a method including providing a substrate including a first short channel active region, a second short channel active region and a long channel active region, each active region separated from another by a shallow trench isolation (STI); and forming a field effect transistor (FET) with a polysilicon gate over the long channel active region, a first dual metal gate FET having a first work function adjusting material over the first short channel active region and a second dual metal gate FET having a second work function adjusting material over the second short channel active region, wherein the first and second work function adjusting materials are different. | 01-14-2010 |
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 |
20110183486 | TRANSISTOR HAVING V-SHAPED EMBEDDED STRESSOR - A semiconductor device and a method of making the device are provided. The method can include forming a gate conductor overlying a major surface of a monocrystalline semiconductor region and forming first spacers on exposed walls of the gate conductor. Using the gate conductor and the first spacers as a mask, at least extension regions are implanted in the semiconductor region and dummy spacers are formed extending outward from the first spacers. Using the dummy spacers as a mask, the semiconductor region is etched to form recesses having at least substantially straight walls extending downward from the major surface to a bottom surface, such that a substantial angle is defined between the bottom surface and the walls. Subsequently, the process is continued by epitaxially growing regions of stressed monocrystalline semiconductor material within the recesses. Then the dummy spacers are removed and the transistor can be completed by forming source/drain regions of the transistor that are at least partially disposed in the stressed semiconductor material regions. | 07-28-2011 |
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 |
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 |
20120119294 | CREATING ANISOTROPICALLY DIFFUSED JUNCTIONS IN FIELD EFFECT TRANSISTOR DEVICES - A method of forming a transistor device includes implanting a diffusion inhibiting species in a semiconductor-on-insulator substrate comprising a bulk substrate, a buried insulator layer, and a semiconductor-on-insulator layer, the semiconductor-on-insulator substrate having one or more gate structures formed thereon such that the diffusion inhibiting species is disposed in portions of the semiconductor-on-insulator layer corresponding to a channel region, and disposed in portions of the buried insulator layer corresponding to source and drain regions. A transistor dopant species is introduced in the source and drain regions. An anneal is performed so as to diffuse the transistor dopant species in a substantially vertical direction while substantially preventing lateral diffusion of the transistor dopant species into the channel region. | 05-17-2012 |
20120139081 | STRESS-GENERATING STRUCTURE FOR SEMICONDUCTOR-ON-INSULATOR DEVICES - A stack pad layers including a first pad oxide layer, a pad nitride layer, and a second pad oxide layer are formed on a semiconductor-on-insulator (SOI) substrate. A deep trench extending below a top surface or a bottom surface of a buried insulator layer of the SOI substrate and enclosing at least one top semiconductor region is formed by lithographic methods and etching. A stress-generating insulator material is deposited in the deep trench and recessed below a top surface of the SOI substrate to form a stress-generating buried insulator plug in the deep trench. A silicon oxide material is deposited in the deep trench, planarized, and recessed. The stack of pad layer is removed to expose substantially coplanar top surfaces of the top semiconductor layer and of silicon oxide plugs. The stress-generating buried insulator plug encloses, and generates a stress to, the at least one top semiconductor region. | 06-07-2012 |
20120168874 | STRUCTURE AND METHOD TO IMPROVE THRESHOLD VOLTAGE OF MOSFETS INCLUDING A HIGH K DIELECTRIC - Threshold voltage controlled semiconductor structures are provided in which a conformal nitride-containing liner is located on at least exposed sidewalls of a patterned gate dielectric material having a dielectric constant of greater than silicon oxide. The conformal nitride-containing liner is a thin layer that is formed using a low temperature (less than 500° C.) nitridation process. | 07-05-2012 |
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 |
20130087832 | Tucked Active Region Without Dummy Poly For Performance Boost and Variation Reduction - In one embodiment, a semiconductor device is provided that includes a semiconductor substrate including an active region and at least one trench isolation region at a perimeter of the active region, and a functional gate structure present on a portion of the active region of the semiconductor substrate. Embedded semiconductor regions are present in the active region of the semiconductor substrate on opposing sides of the portion of the active region that the functional gate structure is present on. A portion of the active region of the semiconductor substrate separates the outermost edge of the embedded semiconductor regions from the at least one isolation region. Methods of forming the aforementioned device are also provided. | 04-11-2013 |
20130099281 | POST-GATE SHALLOW TRENCH ISOLATION STRUCTURE FORMATION - Doped wells, gate stacks, and embedded source and drain regions are formed on, or in, a semiconductor substrate, followed by formation of shallow trenches in the semiconductor substrate. The shallow trenches can be formed by forming a planarized material layer over the doped wells, the gate stacks, and the embedded source and drain regions; patterning the planarized material layer; and transferring the pattern in the planarized material layer into the gate stacks, embedded source and drain regions, and the doped wells. The shallow trenches are filled with a dielectric material to form shallow trench isolation structures. Alternately, the shallow trenches can be formed by applying a photoresist over the doped wells, the gate stacks, and the embedded source and drain regions, and subsequently etching exposed portions of the underlying structures. After removal of the photoresist, shallow trench isolation structures can be formed by filling the shallow trenches. | 04-25-2013 |
20130099313 | FINFET STRUCTURE AND METHOD TO ADJUST THRESHOLD VOLTAGE IN A FINFET STRUCTURE - FinFET structures and methods of manufacturing the FinFET structures are disclosed. The method includes performing an oxygen anneal process on a gate stack of a FinFET structure to induce Vt shift. The oxygen anneal process is performed after sidewall pull down and post silicide. | 04-25-2013 |
20130126976 | SELECTIVE PARTIAL GATE STACK FOR IMPROVED DEVICE ISOLATION - A complementary metal oxide semiconductor (CMOS) device that may include a substrate having a first active region and a second active region that are separated from one another by an isolation region. An n-type semiconductor device is present on the first active region that includes a first gate structure having a first gate dielectric layer and an n-type work function metal layer, wherein the n-type work function layer does not extend onto the isolation region. A p-type semiconductor device is present on the second active region that includes a second gate structure having a second gate dielectric layer and a p-type work function metal layer, wherein the p-type work function layer does not extend onto the isolation region. A connecting gate structure extends across the isolation region into direct contact with the first gate structure and the second gate structure. | 05-23-2013 |
20130168695 | CMOS HAVING A SIC/SIGE ALLOY STACK - A delta doping of silicon by carbon is provided on silicon surfaces by depositing a silicon carbon alloy layer on silicon surfaces, which can be horizontal surfaces of a bulk silicon substrate, horizontal surfaces of a top silicon layer of a semiconductor-on-insulator substrate, or vertical surfaces of silicon fins. A p-type field effect transistor (PFET) region and an n-type field effect transistor (NFET) region can be differentiated by selectively depositing a silicon germanium alloy layer in the PFET region, and not in the NFET region. The silicon germanium alloy layer in the PFET region can overlie or underlie a silicon carbon alloy layer. A common material stack can be employed for gate dielectrics and gate electrodes for a PFET and an NFET. Each channel of the PFET and the NFET includes a silicon carbon alloy layer, and is differentiated by the presence or absence of a silicon germanium layer. | 07-04-2013 |
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 |
20130273699 | MOS HAVING A SIC/SIGE ALLOY STACK - A delta doping of silicon by carbon is provided on silicon surfaces by depositing a silicon carbon alloy layer on silicon surfaces, which can be horizontal surfaces of a bulk silicon substrate, horizontal surfaces of a top silicon layer of a semiconductor-on-insulator substrate, or vertical surfaces of silicon fins. A p-type field effect transistor (PFET) region and an n-type field effect transistor (NFET) region can be differentiated by selectively depositing a silicon germanium alloy layer in the PFET region, and not in the NFET region. The silicon germanium alloy layer in the PFET region can overlie or underlie a silicon carbon alloy layer. A common material stack can be employed for gate dielectrics and gate electrodes for a PFET and an NFET. Each channel of the PFET and the NFET includes a silicon carbon alloy layer, and is differentiated by the presence or absence of a silicon germanium layer. | 10-17-2013 |
20140042541 | CREATING ANISOTROPICALLY DIFFUSED JUNCTIONS IN FIELD EFFECT TRANSISTOR DEVICES - A method of forming a transistor device includes implanting a diffusion inhibiting species in a semiconductor-on-insulator substrate comprising a bulk substrate, a buried insulator layer, and a semiconductor-on-insulator layer, the semiconductor-on-insulator substrate having one or more gate structures formed thereon such that the diffusion inhibiting species is disposed in portions of the semiconductor-on-insulator layer corresponding to a channel region, and disposed in portions of the buried insulator layer corresponding to source and drain regions. A transistor dopant species is introduced in the source and drain regions. An anneal is performed so as to diffuse the transistor dopant species in a substantially vertical direction while substantially preventing lateral diffusion of the transistor dopant species into the channel region. | 02-13-2014 |
20140070274 | POST-GATE SHALLOW TRENCH ISOLATION STRUCTURE FORMATION - Doped wells, gate stacks, and embedded source and drain regions are formed on, or in, a semiconductor substrate, followed by formation of shallow trenches in the semiconductor substrate. The shallow trenches can be formed by forming a planarized material layer over the doped wells, the gate stacks, and the embedded source and drain regions; patterning the planarized material layer; and transferring the pattern in the planarized material layer into the gate stacks, embedded source and drain regions, and the doped wells. The shallow trenches are filled with a dielectric material to form shallow trench isolation structures. Alternately, the shallow trenches can be formed by applying a photoresist over the doped wells, the gate stacks, and the embedded source and drain regions, and subsequently etching exposed portions of the underlying structures. After removal of the photoresist, shallow trench isolation structures can be formed by filling the shallow trenches. | 03-13-2014 |
20140191295 | DUMMY GATE INTERCONNECT FOR SEMICONDUCTOR DEVICE - A method of forming a semiconductor device comprising a dummy gate interconnect includes forming a dummy gate on a substrate, the dummy gate comprising a dummy gate metal layer located on the substrate, and a dummy gate polysilicon layer located on the dummy gate metal layer; forming an active gate on the substrate, the active gate comprising an active gate metal layer located on the substrate, and an active gate polysilicon layer located on the active gate metal layer; and etching the dummy gate polysilicon layer to remove at least a portion of the dummy gate polysilicon layer to form the dummy gate interconnect, wherein the active gate polysilicon layer is not etched during the etching of the dummy gate polysilicon layer. | 07-10-2014 |
20140191325 | Fin-Shaped Field Effect Transistor (FINFET) Structures Having Multiple Threshold Voltages (Vt) and Method of Forming - Various embodiments include fin-shaped field effect transistor (finFET) structures that enhance work function and threshold voltage (Vt) control, along with methods of forming such structures. The finFET structures can include a p-type field effect transistor (PFET) and an n-type field effect transistor (NFET). In some embodiments, the PFET has fins separated by a first distance and the NFET has fins separated by a second distance, where the first distance and the second distance are distinct from one another. In some embodiments, the PFET or the NFET include fins that are separated from one another by non-uniform distances. In some embodiments, the PFET or the NFET include adjacent fins that are separated by distinct distances at their source and drain regions. | 07-10-2014 |
20140319694 | ANTICIPATORY IMPLANT FOR TSV - A method including implanting a region of a substrate with a dopant, and forming a through-substrate via in the substrate adjacent to a device, the through-substrate via passing through the region. | 10-30-2014 |
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 |
20150054093 | FINFET STRUCTURE AND METHOD TO ADJUST THRESHOLD VOLTAGE IN A FINFET STRUCTURE - FinFET structures and methods of manufacturing the FinFET structures are disclosed. The method includes performing an oxygen anneal process on a gate stack of a FinFET structure to induce Vt shift. The oxygen anneal process is performed after sidewall pull down and post silicide. | 02-26-2015 |