| Patent application number | Description | Published |
|---|
| 20090108373 | Techniques for Enabling Multiple Vt Devices Using High-K Metal Gate Stacks - Techniques for combining transistors having different threshold voltage requirements from one another are provided. In one aspect, a semiconductor device comprises a substrate having a first and a second nFET region, and a first and a second pFET region; a logic nFET on the substrate over the first nFET region; a logic pFET on the substrate over the first pFET region; a SRAM nFET on the substrate over the second nFET region; and a SRAM pFET on the substrate over the second pFET region, each comprising a gate stack having a metal layer over a high-K layer. The logic nFET gate stack further comprises a capping layer separating the metal layer from the high-K layer, wherein the capping layer is further configured to shift a threshold voltage of the logic nFET relative to a threshold voltage of one or more of the logic pFET, SRAM nFET and SRAM pFET. | 04-30-2009 |
| 20100038725 | CHANGING EFFECTIVE WORK FUNCTION USING ION IMPLANTATION DURING DUAL WORK FUNCTION METAL GATE INTEGRATION - Ion implantation to change an effective work function for dual work function metal gate integration is presented. One method may include forming a high dielectric constant (high-k) layer over a first-type field effect transistor (FET) region and a second-type FET region; forming a metal layer having a first effective work function compatible for a first-type FET over the first-type FET region and the second-type FET region; and changing the first effective work function to a second, different effective work function over the second-type FET region by implanting a species into the metal layer over the second-type FET region. | 02-18-2010 |
| 20100038736 | SUSPENDED GERMANIUM PHOTODETECTOR FOR SILICON WAVEGUIDE - A vertical stack of a first silicon germanium alloy layer, a second epitaxial silicon layer, a second silicon germanium layer, and a germanium layer are formed epitaxially on a top surface of a first epitaxial silicon layer. The second epitaxial silicon layer, the second silicon germanium layer, and the germanium layer are patterned and encapsulated by a dielectric cap portion, a dielectric spacer, and the first silicon germanium layer. The silicon germanium layer is removed between the first and second silicon layers to form a silicon germanium mesa structure that structurally support an overhanging structure comprising a stack of a silicon portion, a silicon germanium alloy portion, a germanium photodetector, and a dielectric cap portion. The germanium photodetector is suspended by the silicon germanium mesa structure and does not abut a silicon waveguide. Germanium diffusion into the silicon waveguide and defect density in the germanium detector are minimized. | 02-18-2010 |
| 20100164011 | Techniques for Enabling Multiple Vt Devices Using High-K Metal Gate Stacks - Techniques for combining transistors having different threshold voltage requirements from one another are provided. In one aspect, a semiconductor device comprises a substrate having a first and a second nFET region, and a first and a second pFET region; a logic nFET on the substrate over the first nFET region; a logic pFET on the substrate over the first pFET region; a SRAM nFET on the substrate over the second nFET region; and a SRAM pFET on the substrate over the second pFET region, each comprising a gate stack having a metal layer over a high-K layer. The logic nFET gate stack further comprises a capping layer separating the metal layer from the high-K layer, wherein the capping layer is further configured to shift a threshold voltage of the logic nFET relative to a threshold voltage of one or more of the logic pFET, SRAM nFET and SRAM pFET. | 07-01-2010 |
| 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 |
| 20100320547 | SCAVANGING METAL STACK FOR A HIGH-K GATE DIELECTRIC - A stack of a high-k gate dielectric and a metal gate structure includes a lower metal layer, a scavenging metal layer, and an upper metal layer. The scavenging metal layer meets the following two criteria 1) a metal (M) for which the Gibbs free energy change of the reaction Si+2/y M | 12-23-2010 |
| 20110143482 | SUSPENDED GERMANIUM PHOTODETECTOR FOR SILICON WAVEGUIDE - A vertical stack of a first silicon germanium alloy layer, a second epitaxial silicon layer, a second silicon germanium layer, and a germanium layer are formed epitaxially on a top surface of a first epitaxial silicon layer. The second epitaxial silicon layer, the second silicon germanium layer, and the germanium layer are patterned and encapsulated by a dielectric cap portion, a dielectric spacer, and the first silicon germanium layer. The silicon germanium layer is removed between the first and second silicon layers to form a silicon germanium mesa structure that structurally support an overhanging structure comprising a stack of a silicon portion, a silicon germanium alloy portion, a germanium photodetector, and a dielectric cap portion. The germanium photodetector is suspended by the silicon germanium mesa structure and does not abut a silicon waveguide. Germanium diffusion into the silicon waveguide and defect density in the germanium detector are minimized. | 06-16-2011 |
| 20110175147 | FIELD-EFFECT TRANSISTOR DEVICE HAVING A METAL GATE STACK WITH AN OXYGEN BARRIER LAYER - A field effect transistor device and method which includes a semiconductor substrate, a dielectric gate layer, preferably a high dielectric constant gate layer, overlaying the semiconductor substrate and an electrically conductive oxygen barrier layer overlaying the gate dielectric layer. In one embodiment, there is a conductive layer between the gate dielectric layer and the oxygen barrier layer. In another embodiment, there is a low resistivity metal layer on the oxygen barrier layer. | 07-21-2011 |
| 20110175176 | HIGH-K TRANSISTORS WITH LOW THRESHOLD VOLTAGE - A method for forming a semiconductor structure is disclosed. The method includes forming a high-k dielectric layer over a semiconductor substrate and forming a gate layer over the high-k dielectric layer. The method also includes heating the gate layer to 350° C., wherein, if the gate layer includes non-conductive material, the non-conductive material becomes conductive. The method further includes annealing the substrate, the high-k dielectric layer, and the gate layer in excess of 350° C. and, during the annealing, applying a negative electrical bias to the gate layer relative to the semiconductor substrate. A semiconductor structure is also disclosed. The semiconductor structure includes a high-k dielectric layer over a semiconductor substrate, and a gate layer over the high-k dielectric layer. The gate layer has a negative electrical bias during anneal. A p-channel FET including this semiconductor structure is also disclosed. | 07-21-2011 |
| 20110207280 | SCAVANGING METAL STACK FOR A HIGH-K GATE DIELECTRIC - A stack of a high-k gate dielectric and a metal gate structure includes a lower metal layer, a scavenging metal layer, and an upper metal layer. The scavenging metal layer meets the following two criteria 1) a metal (M) for which the Gibbs free energy change of the reaction Si+2/y M | 08-25-2011 |
| 20110241091 | CONTROLLING FERROELECTRICITY IN DIELECTRIC FILMS BY PROCESS INDUCED UNIAXIAL STRAIN - A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress. | 10-06-2011 |
| 20120147666 | PHASE CHANGE MATERIAL CELL WITH STRESS INDUCER LINER - An example embodiment disclosed is a phase change memory cell. The memory cell includes a phase change material and a transducer positioned proximate the phase change material. The phase change material is switchable between at least an amorphous state and a crystalline state. The transducer is configured to activate when the phase change material is changed from the amorphous state to the crystalline state. In a particular embodiment, the transducer is ferroelectric material. | 06-14-2012 |
| 20120181610 | Techniques for Enabling Multiple Vt Devices Using High-K Metal Gate Stacks - Techniques for combining transistors having different threshold voltage requirements from one another are provided. In one aspect, a semiconductor device comprises a substrate having a first and a second nFET region, and a first and a second pFET region; a logic nFET on the substrate over the first nFET region; a logic pFET on the substrate over the first pFET region; a SRAM nFET on the substrate over the second nFET region; and a SRAM pFET on the substrate over the second pFET region, each comprising a gate stack having a metal layer over a high-K layer. The logic nFET gate stack further comprises a capping layer separating the metal layer from the high-K layer, wherein the capping layer is further configured to shift a threshold voltage of the logic nFET relative to a threshold voltage of one or more of the logic pFET, SRAM nFET and SRAM pFET. | 07-19-2012 |
| 20120193348 | HIGH-K TRANSISTORS WITH LOW THRESHOLD VOLTAGE - An apparatus includes a wafer annealing tool and a plurality of electrodes coupled to the wafer annealing tool, wherein the electrodes are configured to be in physical contact with a wafer so that, when the wafer is annealed, a negative electrical bias is formed across one or more gate stacks of the wafer. | 08-02-2012 |
| 20120193716 | HIGH-K TRANSISTORS WITH LOW THRESHOLD VOLTAGE - A semiconductor structure includes a high-k dielectric layer over a semiconductor substrate; and a gate layer over the high-k dielectric layer, wherein the gate layer has a negative electrical bias during anneal. | 08-02-2012 |
| 20120228773 | LARGE-GRAIN, LOW-RESISTIVITY TUNGSTEN ON A CONDUCTIVE COMPOUND - A layered structure and semiconductor device and methods for fabricating a layered structure and semiconductor device. The layered structure includes: a base layer including a material containing titanium nitride, tantalum nitride, or a combination thereof; a conductive layer including a material containing: tantalum aluminum nitride, titanium aluminum nitride, tantalum silicon nitride, titanium silicon nitride, tantalum hafnium nitride, titanium hafnium nitride, hafnium nitride, hafnium carbide, tantalum carbide, vanadium nitride, niobium nitride, or any combination thereof; and a tungsten layer. The semiconductor device includes: a semiconductor substrate; a base layer; a conductive layer; and a tungsten layer. | 09-13-2012 |
| 20120248537 | FABRICATION OF DEVICES HAVING DIFFERENT INTERFACIAL OXIDE THICKNESS VIA LATERAL OXIDATION - A method for forming a semiconductor device includes forming a first field effect transistor (FET) and a second FET on a substrate, the first FET comprising a first interfacial oxide layer, and the second FET comprising a second interfacial oxide layer; encapsulating the first interfacial oxide layer of the first FET; and performing lateral oxidation of the second interfacial oxide layer of the second FET, wherein the lateral oxidation of the second interfacial oxide layer of the second FET converts a portion of the substrate located underneath the second FET into additional interfacial oxide. | 10-04-2012 |
| 20120286340 | CONTROLLING FERROELECTRICITY IN DIELECTRIC FILMS BY PROCESS INDUCED UNIAXIAL STRAIN - A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress. | 11-15-2012 |
| 20120292677 | FERROELECTRIC SEMICONDUCTOR TRANSISTOR DEVICES HAVING GATE MODULATED CONDUCTIVE LAYER - Ferroelectric semiconductor switching devices are provided, including field effect transistor (FET) devices having gate stack structures formed with a ferroelectric layer disposed between a gate contact and a thin conductive layer (“quantum conductive layer”) . The gate contact and ferroelectric layer serve to modulate an effective work function of the thin conductive layer. The thin conductive layer with the modulated work function is coupled to a semiconductor channel layer to modulate current flow through the semiconductor and achieve a steep sub-threshold slope. | 11-22-2012 |
| 20120306019 | FABRICATION OF DEVICES HAVING DIFFERENT INTERFACIAL OXIDE THICKNESS VIA LATERAL OXIDATION - A semiconductor device includes a first field effect transistor (FET) and a second FET located on a substrate, the first FET comprising a first interfacial oxide layer, and the second FET comprising a second interfacial oxide layer, wherein the second interfacial oxide layer of the second FET is thicker than the first interfacial oxide layer of the first FET; and a recess located in the substrate adjacent to the second FET. | 12-06-2012 |
| 20120326314 | LARGE-GRAIN, LOW-RESISTIVITY TUNGSTEN ON A CONDUCTIVE COMPOUND - A layered structure and semiconductor device and methods for fabricating a layered structure and semiconductor device. The layered structure includes: a base layer including a material containing titanium nitride, tantalum nitride, or a combination thereof; a conductive layer including a material containing: tantalum aluminum nitride, titanium aluminum nitride, tantalum silicon nitride, titanium silicon nitride, tantalum hafnium nitride, titanium hafnium nitride, hafnium nitride, hafnium carbide, tantalum carbide, vanadium nitride, niobium nitride, or any combination thereof; and a tungsten layer. The semiconductor device includes: a semiconductor substrate; a base layer; a conductive layer; and a tungsten layer. | 12-27-2012 |
| 20130001668 | FLOATING GATE DEVICE WITH OXYGEN SCAVENGING ELEMENT - A floating gate device is provided. A tunnel oxide layer is formed over the channel. A floating gate is formed over the tunnel oxide layer. A high-k dielectric layer is formed over the floating gate. A control gate is formed over the high-k dielectric layer. At least one of the control gate and/or the floating gate includes an oxygen scavenging element. The oxygen scavenging element is configured to decrease an oxygen density at least one of at a first interface between the control gate and the high-k dielectric layer, at a second interface between the high-k dielectric layer and the floating gate, at a third interface between the floating gate and the tunnel oxide layer, and at a fourth interface between the tunnel oxide layer and the channel responsive to annealing. | 01-03-2013 |
| 20130001743 | METAL INSULATOR METAL STRUCTURE WITH REMOTE OXYGEN SCAVENGING - A structure includes a first metallic electrode, a dielectric film formed over the first metallic electrode, and a second metallic electrode formed over the dielectric film. The second metallic electrode includes an oxygen scavenging material. The oxygen scavenging material is selected such that an oxygen density decreases in a region between the first metallic electrode and the second metallic electrode responsive to elevating a temperature of the first metallic electrode, the dielectric film, and the second metallic electrode. | 01-03-2013 |
| 20130005132 | Floating gate device with oxygen scavenging element - A floating gate device is provided. A tunnel oxide layer is formed over the channel. A floating gate is formed over the tunnel oxide layer. A high-k dielectric layer is formed over the floating gate. A control gate is formed over the high-k dielectric layer. At least one of the control gate and/or the floating gate includes an oxygen scavenging element. The oxygen scavenging element is configured to decrease an oxygen density at least one of at a first interface between the control gate and the high-k dielectric layer, at a second interface between the high-k dielectric layer and the floating gate, at a third interface between the floating gate and the tunnel oxide layer, and at a fourth interface between the tunnel oxide layer and the channel responsive to annealing. | 01-03-2013 |
| 20130032886 | Low Threshold Voltage And Inversion Oxide Thickness Scaling For A High-K Metal Gate P-Type MOSFET - A structure has a semiconductor substrate and an nFET and a pFET disposed upon the substrate. The pFET has a semiconductor SiGe channel region formed upon or within a surface of the semiconductor substrate and a gate dielectric having an oxide layer overlying the channel region and a high-k dielectric layer overlying the oxide layer. A gate electrode overlies the gate dielectric and has a lower metal layer abutting the high-k layer, a scavenging metal layer abutting the lower metal layer, and an upper metal layer abutting the scavenging metal layer. The metal layer scavenges oxygen from the substrate (nFET) and SiGe (pFET) interface with the oxide layer resulting in an effective reduction in T | 02-07-2013 |
| 20130034940 | Low Threshold Voltage And Inversion Oxide thickness Scaling For A High-K Metal Gate P-Type MOSFET - A method of forming a semiconductor structure. The semiconductor structure has a semiconductor substrate and an nFET and a pFET disposed upon the substrate. The pFET has a semiconductor SiGe channel region formed upon or within a surface of the semiconductor substrate and a gate dielectric having an oxide layer overlying the channel region and a high-k dielectric layer overlying the oxide layer. A gate electrode overlies the gate dielectric and has a lower metal layer abutting the high-k layer, a scavenging metal layer abutting the lower metal layer, and an upper metal layer abutting the scavenging metal layer. The metal layer scavenges oxygen from the substrate (nFET) and SiGe (pFET) interface with the oxide layer resulting in an effective reduction in T | 02-07-2013 |
| 20130175633 | CONTROLLING THRESHOLD VOLTAGE IN CARBON BASED FIELD EFFECT TRANSISTORS - A field effect transistor fabrication method includes defining a gate structure on a substrate, depositing a dielectric layer on the gate structure, depositing a first metal layer on the dielectric layer, removing a portion of the first metal layer, depositing a second metal layer, annealing the first and second metal layers, and defining a carbon based device on the dielectric layer and the gate structure. | 07-11-2013 |
| 20130309782 | PHASE CHANGE MATERIAL CELL WITH PIEZOELECTRIC OR FERROELECTRIC STRESS INDUCER LINER - An example embodiment disclosed is a process for fabricating a phase change memory cell. The method includes forming a bottom electrode, creating a pore in an insulating layer above the bottom electrode, depositing piezoelectric material in the pore, depositing phase change material in the pore proximate the piezoelectric material, and forming a top electrode over the phase change material. Depositing the piezoelectric material in the pore may include conforming the piezoelectric material to at least one wall defining the pore such that the piezoelectric material is deposited between the phase change material and the wall. The conformal deposition may be achieved by chemical vapor deposition (CVD) or by atomic layer deposition (ALD). | 11-21-2013 |
| 20140001516 | REDUCING THE INVERSION OXIDE THICKNESS OF A HIGH-K STACK FABRICATED ON HIGH MOBILITY SEMICONDUCTOR MATERIAL | 01-02-2014 |
| 20140004674 | REDUCING THE INVERSION OXIDE THICKNESS OF A HIGH-K STACK FABRICATED ON HIGH MOBILITY SEMICONDUCTOR MATERIAL | 01-02-2014 |
| 20140021470 | INTEGRATED CIRCUIT DEVICE INCLUDING LOW RESISTIVITY TUNGSTEN AND METHODS OF FABRICATION - An integrated circuit device includes a semiconductor substrate and a gate electrode on the semiconductor substrate. The gate electrode structure includes an insulating layer of a dielectric material on the semiconductor substrate, an oxygen barrier layer on the insulating layer, and a tungsten (W) metal layer on the oxygen barrier layer. | 01-23-2014 |
| 20140024208 | INTEGRATED CIRCUIT DEVICE INCLUDING LOW RESISTIVITY TUNGSTEN AND METHODS OF FABRICATION - An integrated circuit device includes a semiconductor substrate and a gate electrode on the semiconductor substrate. The gate electrode structure includes an insulating layer of a dielectric material on the semiconductor substrate, an oxygen barrier layer on the insulating layer, and a tungsten (W) metal layer on the oxygen barrier layer. Also disclosed are methods for fabricating the device. | 01-23-2014 |
| 20140038403 | HIGH-K TRANSISTORS WITH LOW THRESHOLD VOLTAGE - An apparatus includes a wafer annealing tool and a plurality of electrodes coupled to the wafer annealing tool, wherein the electrodes are configured to be in physical contact with a wafer so that, when the wafer is annealed, a negative electrical bias is formed across one or more gate stacks of the wafer. | 02-06-2014 |
| 20140042546 | STRUCTURE AND METHOD TO FORM INPUT/OUTPUT DEVICES - A limited number of cycles of atomic layer deposition (ALD) of Hi-K material followed by deposition of an interlayer dielectric and application of further Hi-K material and optional but preferred annealing provides increased Hi-K material content and increased breakdown voltage for input/output (I/O) transistors compared with logic transistors formed on the same chip or wafer while providing scalability of the inversion layer of the I/O and logic transistors without significantly compromising performance or bias temperature instability (BTI) parameters. | 02-13-2014 |
| 20140103457 | FIELD EFFECT TRANSISTOR DEVICE HAVING A HYBRID METAL GATE STACK - A semiconductor device including a gate structure present on a channel portion of a semiconductor substrate and at least one gate sidewall spacer adjacent to the gate structure. In one embodiment, the gate structure includes a work function metal layer present on a gate dielectric layer, a metal semiconductor alloy layer present on a work function metal layer, and a dielectric capping layer present on the metal semiconductor alloy layer. The at least one gate sidewall spacer and the dielectric capping layer may encapsulate the metal semiconductor alloy layer within the gate structure. | 04-17-2014 |
| 20140106531 | FIELD EFFECT TRANSISTOR DEVICE HAVING A HYBRID METAL GATE STACK - A semiconductor device including a gate structure present on a channel portion of a semiconductor substrate and at least one gate sidewall spacer adjacent to the gate structure. In one embodiment, the gate structure includes a work function metal layer present on a gate dielectric layer, a metal semiconductor alloy layer present on a work function metal layer, and a dielectric capping layer present on the metal semiconductor alloy layer. The at least one gate sidewall spacer and the dielectric capping layer may encapsulate the metal semiconductor alloy layer within the gate structure. | 04-17-2014 |
| 20140162447 | FINFET HYBRID FULL METAL GATE WITH BORDERLESS CONTACTS - A method for fabricating a field effect transistor device includes patterning a fin on substrate, patterning a gate stack over a portion of the fin and a portion of an insulator layer arranged on the substrate, forming a protective barrier over the gate stack, a portion of the fin and a portion of the insulator layer, the protective barrier enveloping the gate stack, depositing a second insulator layer over portions of the fin and the protective barrier, performing a first etching process to selectively remove portions of the second insulator layer to define cavities that expose portions of source and drain regions of the fin without appreciably removing the protective barrier, and depositing a conductive material in the cavities. | 06-12-2014 |
| 20140252492 | GATE STACK INCLUDING A HIGH-K GATE DIELECTRIC THAT IS OPTIMIZED FOR LOW VOLTAGE APPLICATIONS - A method of forming a semiconductor device that includes forming a high-k gate dielectric layer on a semiconductor substrate, wherein an oxide containing interfacial layer can be present between the high-k gate dielectric layer and the semiconductor substrate. A scavenging metal stack may be formed on the high-k gate dielectric layer. An annealing process may be applied to the scavenging metal stack during which the scavenging metal stack removes oxide material from the oxide containing interfacial layer, wherein the oxide containing interfacial layer is thinned by removing of the oxide material. A gate conductor layer is formed on the high-k gate dielectric layer. The gate conductor layer and the high-k gate dielectric layer are then patterned to provide a gate structure. A source region and a drain region are then formed on opposing sides of the gate structure. | 09-11-2014 |
| 20140252493 | GATE STACK INCLUDING A HIGH-K GATE DIELECTRIC THAT IS OPTIMIZED FOR LOW VOLTAGE APPLICATIONS - A method of forming a semiconductor device that includes forming a high-k gate dielectric layer on a semiconductor substrate, wherein an oxide containing interfacial layer can be present between the high-k gate dielectric layer and the semiconductor substrate. A scavenging metal stack may be formed on the high-k gate dielectric layer. An annealing process may be applied to the scavenging metal stack during which the scavenging metal stack removes oxide material from the oxide containing interfacial layer, wherein the oxide containing interfacial layer is thinned by removing of the oxide material. A gate conductor layer is formed on the high-k gate dielectric layer. The gate conductor layer and the high-k gate dielectric layer are then patterned to provide a gate structure. A source region and a drain region are then formed on opposing sides of the gate structure. | 09-11-2014 |
| 20140264638 | GATE STACK OF BORON SEMICONDUCTOR ALLOY, POLYSILICON AND HIGH-K GATE DIELECTRIC FOR LOW VOLTAGE APPLICATIONS - A method of forming a gate structure for a semiconductor device that includes forming a non-stoichiometric high-k gate dielectric layer on a semiconductor substrate, wherein an oxide containing interfacial layer can be present between the non-stoichiometric high-k gate dielectric layer and the semiconductor substrate. At least one gate conductor layer may be formed on the non-stoichiometric high-k gate dielectric layer. The at least one gate conductor layer comprises a boron semiconductor alloy layer. An anneal process is applied, wherein during the anneal process the non-stoichiometric high-k gate dielectric layer removes oxide material from the oxide containing interfacial layer. The oxide containing interfacial layer is thinned by removing the oxide material during the anneal process. | 09-18-2014 |
| 20140264639 | GATE STACK OF BORON SEMICONDUCTOR ALLOY, POLYSILICON AND HIGH-K GATE DIELECTRIC FOR LOW VOLTAGE APPLICATIONS - A method of forming a gate structure for a semiconductor device that includes forming a non-stoichiometric high-k gate dielectric layer on a semiconductor substrate, wherein an oxide containing interfacial layer can be present between the non-stoichiometric high-k gate dielectric layer and the semiconductor substrate. At least one gate conductor layer may be formed on the non-stoichiometric high-k gate dielectric layer. The at least one gate conductor layer comprises a boron semiconductor alloy layer. An anneal process is applied, wherein during the anneal process the non-stoichiometric high-k gate dielectric layer removes oxide material from the oxide containing interfacial layer. The oxide containing interfacial layer is thinned by removing the oxide material during the anneal process. | 09-18-2014 |
| 20140308821 | HYDROXYL GROUP TERMINATION FOR NUCLEATION OF A DIELECTRIC METALLIC OXIDE - A surface of a semiconductor-containing dielectric material/oxynitride/nitride is treated with a basic solution in order to provide hydroxyl group termination of the surface. A dielectric metal oxide is subsequently deposited by atomic layer deposition. The hydroxyl group termination provides a uniform surface condition that facilitates nucleation and deposition of the dielectric metal oxide, and reduces interfacial defects between the oxide and the dielectric metal oxide. Further, treatment with the basic solution removes more oxide from a surface of a silicon germanium alloy with a greater atomic concentration of germanium, thereby reducing a differential in the total thickness of the combination of the oxide and the dielectric metal oxide across surfaces with different germanium concentrations. | 10-16-2014 |
| 20140361351 | GATE ELECTRODE WITH STABILIZED METAL SEMICONDUCTOR ALLOY-SEMICONDUCTOR STACK - A gate structure is provided on a channel portion of a semiconductor substrate. The gate structure may include an electrically conducting layer present on a gate dielectric layer, a semiconductor-containing layer present on the electrically conducting layer, a metal semiconductor alloy layer present on the semiconductor-containing layer, and a dielectric capping layer overlaying the metal semiconductor alloy layer. In some embodiments, carbon and/or nitrogen can be present within the semiconductor-containing layer, the metal semiconductor alloy layer or both the semiconductor-containing layer and the metal semiconductor alloy layer. The presence of carbon and/or nitrogen within the semiconductor-containing layer and/or the metal semiconductor alloy layer provides stability to the gate structure. In another embodiment, a layer of carbon and/or nitrogen can be formed between the semiconductor-containing layer and the metal semiconductor alloy layer. | 12-11-2014 |
| 20140363964 | GATE ELECTRODE WITH STABILIZED METAL SEMICONDUCTOR ALLOY-SEMICONDUCTOR STACK - A gate structure is provided on a channel portion of a semiconductor substrate. The gate structure may include an electrically conducting layer present on a gate dielectric layer, a semiconductor-containing layer present on the electrically conducting layer, a metal semiconductor alloy layer present on the semiconductor-containing layer, and a dielectric capping layer overlaying the metal semiconductor alloy layer. In some embodiments, carbon and/or nitrogen can be present within the semiconductor-containing layer, the metal semiconductor alloy layer or both the semiconductor-containing layer and the metal semiconductor alloy layer. The presence of carbon and/or nitrogen within the semiconductor-containing layer and/or the metal semiconductor alloy layer provides stability to the gate structure. In another embodiment, a layer of carbon and/or nitrogen can be formed between the semiconductor-containing layer and the metal semiconductor alloy layer. | 12-11-2014 |
