Patent application number | Description | Published |
20140070285 | METHODS OF FORMING SEMICONDUCTOR DEVICES WITH SELF-ALIGNED CONTACTS AND THE RESULTING DEVICES - One method includes forming a sacrificial gate structure above a substrate, forming a first sidewall spacer adjacent a sacrificial gate electrode, removing a portion of the first sidewall spacer to expose a portion of the sidewalls of the sacrificial gate electrode, and forming a liner layer on the exposed sidewalls of the sacrificial gate electrode and above a residual portion of the first sidewall spacer. The method further includes forming a first layer of insulating material above the liner layer, forming a second sidewall spacer above the first layer of insulating material and adjacent the liner layer, performing an etching process to remove the second sidewall spacer and sacrificial gate cap layer to expose an upper surface of the sacrificial gate electrode, removing the sacrificial gate electrode to define a gate cavity at least partially defined laterally by the liner layer, and forming a replacement gate structure in the cavity. | 03-13-2014 |
20140084383 | METHODS OF FORMING 3-D SEMICONDUCTOR DEVICES USING A REPLACEMENT GATE TECHNIQUE AND A NOVEL 3-D DEVICE - One illustrative method disclosed herein includes forming a sacrificial gate structure above a fin, wherein the sacrificial gate structure is comprised of a sacrificial gate insulation layer, a layer of insulating material, a sacrificial gate electrode layer and a gate cap layer, forming a sidewall spacer adjacent opposite sides of the sacrificial gate structure, removing the sacrificial gate structure to thereby define a gate cavity that exposes a portion of the fin, and forming a replacement gate structure in the gate cavity. One illustrative device disclosed herein includes a plurality of fin structures that are separated by a trench formed in a substrate, a local isolation material positioned within the trench, a gate structure positioned around portions of the fin structures and above the local isolation material and an etch stop layer positioned between the gate structure and the local isolation material within the trench. | 03-27-2014 |
20140110794 | FACILITATING GATE HEIGHT UNIFORMITY AND INTER-LAYER DIELECTRIC PROTECTION - Methods of facilitating replacement gate processing and semiconductor devices formed from the methods are provided. The methods include, for instance, providing a plurality of sacrificial gate electrodes with sidewall spacers, the sacrificial gate electrodes with sidewall spacers being separated by, at least in part, a first dielectric material, wherein the first dielectric material is recessed below upper surfaces of the sacrificial gate electrodes, and the upper surfaces of the sacrificial gate electrodes are exposed and coplanar; conformally depositing a protective film over the sacrificial gate electrodes, the sidewall spacers, and the first dielectric material; providing a second dielectric material over the protective film, and planarizing the second dielectric material, stopping on and exposing the protective film over the sacrificial gate electrodes; and opening the protective film over the sacrificial gate electrodes to facilitate performing a replacement gate process. | 04-24-2014 |
20140124840 | PREVENTION OF FIN EROSION FOR SEMICONDUCTOR DEVICES - A dielectric metal compound liner can be deposited on a semiconductor fin prior to formation of a disposable gate structure. The dielectric metal compound liner protects the semiconductor fin during the pattering of the disposable gate structure and a gate spacer. The dielectric metal compound liner can be removed prior to formation of source and drain regions and a replacement gate structure. Alternately, a dielectric metal compound liner can be deposited on a semiconductor fin and a gate stack, and can be removed after formation of a gate spacer. Further, a dielectric metal compound liner can be deposited on a semiconductor fin and a disposable gate structure, and can be removed after formation of a gate spacer and removal of the disposable gate structure. The dielectric metal compound liner can protect the semiconductor fin during formation of the gate spacer in each embodiment. | 05-08-2014 |
20140124841 | METHODS OF FORMING REPLACEMENT GATE STRUCTURES ON SEMICONDUCTOR DEVICES AND THE RESULTING DEVICE - One method includes forming first sidewall spacers adjacent opposite sides of a sacrificial gate structure and a gate cap layer, removing the gate cap layer and a portion of the first sidewall spacers to define reduced-height first sidewall spacers, forming second sidewall spacers, removing the sacrificial gate structure to thereby define a gate cavity, whereby a portion of the gate cavity is laterally defined by the second sidewall spacers, and forming a replacement gate structure in the gate cavity, wherein at least a first portion of the replacement gate structure is positioned between the second sidewall spacers. A device includes a gate structure positioned above the substrate between first and second spaced-apart portions of a layer of insulating material and a plurality of first sidewall spacers, each of which are positioned between the gate structure and on one of the first and second portions of the layer of insulating material. | 05-08-2014 |
20140159171 | METHODS OF FORMING BULK FINFET SEMICONDUCTOR DEVICES BY PERFORMING A LINER RECESSING PROCESS TO DEFINE FIN HEIGHTS AND FINFET DEVICES WITH SUCH A RECESSED LINER - One method disclosed herein includes forming a conformal liner layer in a plurality of trenches that define a fin, forming a layer of insulating material above the liner layer, exposing portions of the liner layer, removing portions of the liner layer so as to result in a generally U-shaped liner positioned at a bottom of each of the trenches, performing at least one third etching process on the layer of insulating material, wherein at least a portion of the layer of insulating material is positioned within a cavity of the U-shaped liner layer, and forming a gate structure around the fin. A FinFET device disclosed herein includes a plurality of trenches that define a fin, a local isolation that includes a generally U-shaped liner that defines, in part, a cavity and a layer of insulating material positioned within the cavity, and a gate structure positioned around the fin. | 06-12-2014 |
20140191324 | METHODS OF FORMING BULK FINFET DEVICES BY PERFORMING A RECESSING PROCESS ON LINER MATERIALS TO DEFINE DIFFERENT FIN HEIGHTS AND FINFET DEVICES WITH SUCH RECESSED LINER MATERIALS - One method includes performing an etching process through a patterned mask layer to form trenches in a substrate that defines first and second fins, forming liner material adjacent the first fin to a first thickness, forming liner material adjacent the second fin to a second thickness different from the first thickness, forming insulating material in the trenches adjacent the liner materials and above the mask layer, performing a process operation to remove portions of the layer of insulating material and to expose portions of the liner materials, performing another etching process to remove portions of the liner materials and the mask layer to expose the first fin to a first height and the second fin to a second height different from the first height, performing another etching process to define a reduced-thickness layer of insulating material, and forming a gate structure around a portion of the first and second fin. | 07-10-2014 |
20140197468 | METHODS OF FORMING SEMICONDUCTOR DEVICE WITH SELF-ALIGNED CONTACT ELEMENTS AND THE RESULTING DEVICE - One method disclosed includes forming a final gate structure in a gate cavity that is laterally defined by sidewall spacers, removing a portion of the sidewall spacers to define recessed sidewall spacers, removing a portion of the final gate structure to define a recessed final gate structure and forming an etch stop on the recessed sidewall spacers and the recessed final gate structure. A transistor device disclosed herein includes a final gate structure that has an upper surface positioned at a first height level above a surface of a substrate, sidewall spacers positioned adjacent the final gate structure, the sidewall spacers having an upper surface that is positioned at a second, greater height level above the substrate, an etch stop layer formed on the upper surfaces of the sidewall spacers and the final gate structure, and a conductive contact that is conductively coupled to a contact region of the transistor. | 07-17-2014 |
20140217482 | INTEGRATED CIRCUITS HAVING REPLACEMENT GATE STRUCTURES AND METHODS FOR FABRICATING THE SAME - A method of fabricating an integrated circuit includes forming an interlayer dielectric (ILD) layer over a dummy gate stack. The dummy gate stack includes a dummy gate structure, a hardmask layer, and sidewall spacers formed over a semiconductor substrate. The method further includes removing at least an upper portion of the dummy gate stack to form a first opening within the ILD layer, extending the first opening to form a first extended opening by completely removing the dummy gate structure of the dummy gate stack, and depositing at least one workfunction material layer within the first opening and within the first extended opening. Still further, the method includes removing portions of the workfunction material within the first opening and depositing a low-resistance material over remaining portions of the workfunction material thereby forming a replacement metal gate structure that includes the remaining portion of the workfunction material and the low-resistance material. | 08-07-2014 |
20140217517 | INTEGRATED CIRCUITS INCLUDING FINFET DEVICES WITH LOWER CONTACT RESISTANCE AND REDUCED PARASITIC CAPACITANCE AND METHODS FOR FABRICATING THE SAME - Integrated circuits and methods for fabricating integrated circuits are provided. In one example, an integrated circuit includes a semiconductor substrate. A first fin and a second fin are adjacent to each other extending from the semiconductor substrate. The first fin has a first upper section and the second fin has a second upper section. A first epi-portion overlies the first upper section and a second epi-portion overlies the second upper section. A first silicide layer overlies the first epi-portion and a second silicide layer overlies the second epi-portion. The first and second silicide layers are spaced apart from each other to define a lateral gap. A dielectric spacer is formed of a dielectric material and spans the lateral gap. A contact-forming material overlies the dielectric spacer and portions of the first and second silicide layers that are laterally above the dielectric spacer. | 08-07-2014 |
20140231885 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS HAVING METAL GATE ELECTRODES - Integrated circuits and methods for fabricating integrated circuits are provided. In an exemplary embodiment, a method for fabricating integrated circuits includes providing a sacrificial gate structure over a semiconductor substrate. The sacrificial gate structure includes two spacers and sacrificial gate material between the two spacers. The method recesses a portion of the sacrificial gate material between the two spacers. Upper regions of the two spacers are etched while using the sacrificial gate material as a mask. The method includes removing a remaining portion of the sacrificial gate material and exposing lower regions of the two spacers. A first metal is deposited between the lower regions of the two spacers. A second metal is deposited between the upper regions of the two spacers. | 08-21-2014 |
20140231920 | INTEGRATED CIRCUITS WITH IMPROVED GATE UNIFORMITY AND METHODS FOR FABRICATING SAME - Integrated circuits with improved gate uniformity and methods for fabricating such integrated circuits are provided. In an embodiment, an integrated circuit includes a semiconductor substrate and a replacement metal gate structure overlying the semiconductor substrate. The replacement metal gate structure includes a first metal and a second metal and has a recess surface formed by the first metal and the second metal. The first metal and the second metal include a first species of diffused foreign ions. The integrated circuit further includes a metal fill material overlying the recess surface formed by the first metal and the second metal. | 08-21-2014 |
20140252424 | METHODS OF FORMING SEMICONDUCTOR DEVICE WITH SELF-ALIGNED CONTACT ELEMENTS AND THE RESULTING DEVICES - One method discloses performing an etching process to form a contact opening in a layer of insulating material above at least a portion of a source/drain, region wherein, after the completion of the etching process, a portion of a gate structure of the transistor is exposed, selectively forming an oxidizable material on the exposed gate structure, converting at least a portion of the oxidizable material to an oxide material, and forming a conductive contact in the contact opening that is conductively coupled to the source/drain region. A novel transistor device disclosed herein includes an oxide material positioned between a conductive contact and a gate structure of the transistor, wherein the oxide material contacts the conductive contact and contacts a portion, but not all, of the exterior surface of the gate structure. | 09-11-2014 |
20140252425 | METHODS OF FORMING SEMICONDUCTOR DEVICE WITH SELF-ALIGNED CONTACT ELEMENTS AND THE RESULTING DEVICES - One method includes performing a first etching process to form a contact opening in a layer of insulating material that exposes a portion of a gate structure of the transistor, performing a second etching process on the exposed portion of the gate structure to thereby define a gate recess, selectively forming an oxidizable material in the gate recess, converting the oxidizable material to an oxide material, and forming a conductive contact in the contact opening that is conductively coupled to a source/drain region. A device includes an oxide material that is positioned at least partially in a recess formed in a gate structure, wherein the oxide material contacts a conductive contact and contacts a portion, but not all, of the exterior surface of the gate structure. | 09-11-2014 |
20140256106 | PREVENTION OF FIN EROSION FOR SEMICONDUCTOR DEVICES - A dielectric metal compound liner can be deposited on a semiconductor fin prior to formation of a disposable gate structure. The dielectric metal compound liner protects the semiconductor fin during the pattering of the disposable gate structure and a gate spacer. The dielectric metal compound liner can be removed prior to formation of source and drain regions and a replacement gate structure. Alternately, a dielectric metal compound liner can be deposited on a semiconductor fin and a gate stack, and can be removed after formation of a gate spacer. Further, a dielectric metal compound liner can be deposited on a semiconductor fin and a disposable gate structure, and can be removed after formation of a gate spacer and removal of the disposable gate structure. The dielectric metal compound liner can protect the semiconductor fin during formation of the gate spacer in each embodiment. | 09-11-2014 |
20140264479 | METHODS OF INCREASING SPACE FOR CONTACT ELEMENTS BY USING A SACRIFICIAL LINER AND THE RESULTING DEVICE - One method includes forming a sidewall spacer adjacent a gate structure, forming a first liner layer on the sidewall spacer, forming a second liner layer on the first liner layer, forming a first layer of insulating material above the substrate and adjacent the second liner layer, selectively removing at least portions of the second liner layer relative to the first liner layer, forming a second layer of insulating material above the first layer of insulating material, performing at least one second etching process to remove at least portions of the first and second layers of insulating material and at least portions of the first liner layer so as to thereby expose an outer surface of the sidewall spacer, and forming a conductive contact that contacts the exposed outer surface of the sidewall spacer and a source/drain region of the transistor. | 09-18-2014 |
20140315371 | METHODS OF FORMING ISOLATION REGIONS FOR BULK FINFET SEMICONDUCTOR DEVICES - One method disclosed herein includes forming a plurality of fin-formation trenches in a semiconductor substrate that define a plurality of spaced-apart fins, forming a patterned liner layer that covers a portion of the substrate positioned between the fins while exposing portions of the substrate positioned laterally outside of the patterned liner layer, and performing at least one etching process on the exposed portions of the substrate through the patterned liner layer to define an isolation trench in the substrate, wherein the isolation trench has a depth that is greater than a depth of the fin-formation trenches. | 10-23-2014 |
20140327088 | FINFET SEMICONDUCTOR DEVICE WITH A RECESSED LINER THAT DEFINES A FIN HEIGHT OF THE FINFET DEVICE - One method disclosed herein includes forming a conformal liner layer in a plurality of trenches that define a fin, forming a layer of insulating material above the liner layer, exposing portions of the liner layer, removing portions of the liner layer so as to result in a generally U-shaped liner positioned at a bottom of each of the trenches, performing at least one third etching process on the layer of insulating material, wherein at least a portion of the layer of insulating material is positioned within a cavity of the U-shaped liner layer, and forming a gate structure around the fin. A FinFET device disclosed herein includes a plurality of trenches that define a fin, a local isolation that includes a generally U-shaped liner that defines, in part, a cavity and a layer of insulating material positioned within the cavity, and a gate structure positioned around the fin. | 11-06-2014 |
20140327089 | FINFET DEVICES HAVING RECESSED LINER MATERIALS TO DEFINE DIFFERENT FIN HEIGHTS - One method includes performing an etching process through a patterned mask layer to form trenches in a substrate that defines first and second fins, forming liner material adjacent the first fin to a first thickness, forming liner material adjacent the second fin to a second thickness different from the first thickness, forming insulating material in the trenches adjacent the liner materials and above the mask layer, performing a process operation to remove portions of the layer of insulating material and to expose portions of the liner materials, performing another etching process to remove portions of the liner materials and the mask layer to expose the first fin to a first height and the second fin to a second height different from the first height, performing another etching process to define a reduced-thickness layer of insulating material, and forming a gate structure around a portion of the first and second fin. | 11-06-2014 |
20140327090 | FINFET DEVICE WITH AN ETCH STOP LAYER POSITIONED BETWEEN A GATE STRUCTURE AND A LOCAL ISOLATION MATERIAL - One illustrative method disclosed herein includes forming a sacrificial gate structure above a fin, wherein the sacrificial gate structure is comprised of a sacrificial gate insulation layer, a layer of insulating material, a sacrificial gate electrode layer and a gate cap layer, forming a sidewall spacer adjacent opposite sides of the sacrificial gate structure, removing the sacrificial gate structure to thereby define a gate cavity that exposes a portion of the fin, and forming a replacement gate structure in the gate cavity. One illustrative device disclosed herein includes a plurality of fin structures that are separated by a trench formed in a substrate, a local isolation material positioned within the trench, a gate structure positioned around portions of the fin structures and above the local isolation material and an etch stop layer positioned between the gate structure and the local isolation material within the trench. | 11-06-2014 |
20140339629 | CONTACT FORMATION FOR ULTRA-SCALED DEVICES - Embodiments of the invention provide approaches for forming gate and source/drain (S/D) contacts. Specifically, the semiconductor device includes a gate transistor formed over a substrate, a S/D contact formed over a trench-silicide (TS) layer and positioned adjacent the gate transistor, and a gate contact formed over the gate transistor, wherein at least a portion of the gate contact is aligned over the TS layer. This structure enables contact with the TS layer, thereby decreasing the distance between the gate contact and the source/drain, which is desirable for ultra-area-scaling. | 11-20-2014 |
20140346574 | ASYMMETRIC FINFET SEMICONDUCTOR DEVICES AND METHODS FOR FABRICATING THE SAME - Asymmetric FinFET devices and methods for fabricating such devices are provided. In one embodiment, a method includes providing a semiconductor substrate comprising a plurality of fin structures formed thereon and depositing a conformal liner over the fin structures. A first portion of the conformal liner is removed, leaving a first space between the fins structures and forming a first metal gate in the first space between the fin structures. A second portion of the conformal liner is removed, leaving a second space between the fin structures and forming a second metal gate in the second space between the fin structures. | 11-27-2014 |
20140346599 | FINFET SEMICONDUCTOR DEVICES WITH LOCAL ISOLATION FEATURES AND METHODS FOR FABRICATING THE SAME - FinFET semiconductor devices with local isolation features and methods for fabricating such devices are provided. In one embodiment, a method for fabricating a semiconductor device includes providing a semiconductor substrate comprising a plurality of fin structures formed thereon, wherein each of the plurality of fin structures has sidewalls, forming spacers about the sidewalls of the plurality of fin structures, and forming a silicon-containing layer over the semiconductor substrate and in between the plurality of fin structures. The method further includes removing at least a first portion of the silicon-containing layer to form a plurality of void regions while leaving at least a second portion thereof in place and depositing an isolation material in the plurality of void regions. | 11-27-2014 |
20140367788 | METHODS OF FORMING GATE STRUCTURES FOR CMOS BASED INTEGRATED CIRCUIT PRODUCTS AND THE RESULTING DEVICES - One illustrative method disclosed herein includes forming gate insulation layers and a first metal layer for NMOS and PMOS devices from the same material, selectively forming a first metal layer only for the PMOS device, and forming different shaped metal silicide regions within the NMOS and PMOS gate cavities. A novel integrated circuit product disclosed herein includes an NMOS transistor with an NMOS gate insulation layer, an NMOS metal silicide having a generally rectangular cross-sectional configuration and an NMOS metal layer positioned on the NMOS metal silicide region. The product also includes a PMOS transistor with the same gate insulation material, a first PMOS metal and a PMOS metal silicide region, wherein the NMOS and PMOS metal silicide regions are comprised of the same metal silicide. | 12-18-2014 |
20140367790 | METHODS OF FORMING GATE STRUCTURES FOR CMOS BASED INTEGRATED CIRCUIT PRODUCTS AND THE RESULTING DEVICES - One illustrative method disclosed herein includes forming replacement gate structures for an NMOS transistor and a PMOS transistor by forming gate insulation layers and a first metal layer for the devices from the same materials and selectively forming a metal-silicide material layer only on the first metal layer for the NMOS device but not on the PMOS device. One example of a novel integrated circuit product disclosed herein includes an NMOS device and a PMOS device wherein the gate insulation layers and the first metal layer of the gate structures of the devices are made of the same material, the gate structure of the NMOS device includes a metal silicide material positioned on the first metal layer of the NMOS device, and a second metal layer that is positioned on the metal silicide material for the NMOS device and on the first metal layer for the PMOS device. | 12-18-2014 |
20140367795 | METHODS OF FORMING DIFFERENT FINFET DEVICES HAVING DIFFERENT FIN HEIGHTS AND AN INTEGRATED CIRCUIT PRODUCT CONTAINING SUCH DEVICES - One illustrative method disclosed herein includes forming a plurality of trenches in a plurality of active regions of a substrate that defines at least a first plurality of fins and a second plurality of fins for first and second FinFET devices, respectively, forming liner materials adjacent to the first and second plurality of fins, wherein the liner materials adjacent the first fins and the second fins have a different thickness. The method also includes removing insulating material to expose portions of the liner materials, performing an etching process to remove portions of the liner materials so as to expose at least one fin in the first plurality of fins to a first height and at least one of the second plurality of fins to a second height that is different from the first height. | 12-18-2014 |
20150021683 | METHODS OF FORMING SEMICONDUCTOR DEVICE WITH SELF-ALIGNED CONTACT ELEMENTS AND THE RESULTING DEVICES - One method disclosed herein includes forming a sacrificial etch stop material in a recess above a replacement gate structure, with the sacrificial etch stop material in position, forming a self-aligned contact that is conductively coupled to the source/drain region, after forming the self-aligned contact, performing at least one process operation to expose and remove the sacrificial etch stop material in the recess so as to thereby re-expose the recess, and forming a third layer of insulating material in at least the re-exposed recess. | 01-22-2015 |
20150035086 | METHODS OF FORMING CAP LAYERS FOR SEMICONDUCTOR DEVICES WITH SELF-ALIGNED CONTACT ELEMENTS AND THE RESULTING DEVICES - One method disclosed herein includes forming an etch stop layer above recessed sidewall spacers and a recessed replacement gate structure and, with the etch stop layer in position, forming a self-aligned contact that is conductively coupled to the source/drain region after forming the self-aligned contact. A device disclosed herein includes an etch stop layer that is positioned above a recessed replacement gate structure and recessed sidewall spacers, wherein the etch stop layer defines an etch stop recess that contains a layer of insulating material positioned therein. The device further includes a self-aligned contact. | 02-05-2015 |
20150041905 | METHODS OF FORMING REPLACEMENT GATE STRUCTURES FOR TRANSISTORS AND THE RESULTING DEVICES - Disclosed herein are illustrative methods and devices that involve forming spacers with internally trimmed internal surfaces to increase the width of the upper portions of a gate cavity. In some embodiments, the internal surface of the spacer has a stepped cross-sectional configuration or a tapered cross-sectional configuration. In one example, a device is disclosed wherein the P-type work function metal for a PMOS device is positioned only within the lateral space defined by the untrimmed internal surfaces of the spacers, while the work function adjusting metal for the NMOS device is positioned laterally between the lateral spaces defined by both the trimmed and untrimmed internal surfaces of the sidewall spacers. | 02-12-2015 |
20150054078 | METHODS OF FORMING GATE STRUCTURES FOR FINFET DEVICES AND THE RESULTING SMEICONDUCTOR PRODUCTS - One method disclosed herein includes forming a stack of material layers to form gate structures, performing a first etching process to define an opening through the stack of materials that defines an end surface of the gate structures, forming a gate separation structure in the opening and performing a second etching process to define side surfaces of the gate structures. A device disclosed herein includes first and second active regions that include at least one fin, first and second gate structures, wherein each of the gate structures have end surfaces, and a gate separation structure positioned between the gate structures, wherein opposing surfaces of the gate separation structure abut the end surfaces of the gate structures, and wherein an upper surface of the gate separation structure is positioned above an upper surface of the at least one fin. | 02-26-2015 |
20150060960 | METHODS OF FORMING CONTACT STRUCTURES ON FINFET SEMICONDUCTOR DEVICES AND THE RESULTING DEVICES - A method includes forming a raised isolation structure with a recess above a substrate, forming a gate structure above the fin, forming a plurality of spaced-apart buried fin contact structures within the recess that have an outer perimeter surface that contacts at least a portion of an interior perimeter surface of the recess and forming at least one source/drain contact structure for each of the buried fin contact structures. One device includes a plurality of spaced-apart buried fin contact structures positioned within a recess in a raised isolation structure on opposite sides of a gate structure. The upper surface of each of the buried fin contact structures is positioned below an upper surface of the raised isolation structure and an outer perimeter surface of each of the buried fin contact structures contacts at least a portion of an interior perimeter surface of the recess. | 03-05-2015 |
20150069532 | METHODS OF FORMING FINFET SEMICONDUCTOR DEVICES WITH SELF-ALIGNED CONTACT ELEMENTS USING A REPLACEMENT GATE PROCESS AND THE RESULTING DEVICES - One method disclosed herein includes removing a sacrificial gate structure and forming a replacement gate structure in its place, after forming the replacement gate structure, forming a metal silicide layer on an entire upper surface area of each of a plurality of source/drain regions and, with the replacement gate structure in position, forming at least one source/drain contact structure for each of the plurality of source/drain regions, wherein the at least one source/drain contact structure is conductively coupled to a portion of the metal silicide layer and a dimension of the at least one source/drain contact structure in a gate width direction of the transistor is less than a dimension of the source/drain region in the gate width direction. | 03-12-2015 |
20150076609 | METHODS OF FORMING STRESSED LAYERS ON FINFET SEMICONDUCTOR DEVICES AND THE RESULTING DEVICES - One method includes forming a raised isolation structure with a recess above a substrate, forming a gate structure above the fin, forming a plurality of spaced-apart buried fin contact structures within the recess and forming a stress-inducing material layer above the buried fin contact structures. One device includes a plurality of spaced-apart buried fin contact structures positioned within a recess in a raised isolation structure on opposite sides of a gate structure, a stress-inducing material layer formed above the buried fin contact structures and a source/drain contact that extends through the stress-inducing material layer. | 03-19-2015 |