Patent application number | Description | Published |
20090108366 | Structure And Method To Fabricate Metal Gate High-K Devices - Disclosed is a method to fabricate a semiconductor device, and a device fabricated in accordance with the method. The method includes providing a substrate comprised of silicon; performing a shallow trench isolation process to delineate nFET and pFET active areas and, within each active area, forming a gate structure over a surface of the substrate, the gate structure comprising in order from the surface of the substrate, a layer of high dielectric constant oxide, a layer comprised of a metal, a layer comprised of amorphous silicon, and a layer comprised of polycrystalline silicon. The layer comprised of amorphous silicon is provided to substantially prevent regrowth of the high dielectric constant oxide layer in a vertical direction during at least a deposition and processing of the polycrystalline silicon layer and/or metal layer. | 04-30-2009 |
20090302396 | Structure and Method to Fabricate Metal Gate High-K Devices - Disclosed is a method to fabricate a semiconductor device, and a device fabricated in accordance with the method. The method includes providing a substrate comprised of silicon; performing a shallow trench isolation process to delineate nFET and pFET active areas and, within each active area, forming a gate structure over a surface of the substrate, the gate structure comprising in order from the surface of the substrate, a layer of high dielectric constant oxide, a layer comprised of a metal, a layer comprised of amorphous silicon, and a layer comprised of polycrystalline silicon. The layer comprised of amorphous silicon is provided to substantially prevent regrowth of the high dielectric constant oxide layer in a vertical direction during at least a deposition and processing of the polycrystalline silicon layer and/or metal layer. | 12-10-2009 |
20110284967 | Stressed Fin-FET Devices with Low Contact Resistance - A method for fabricating an FET device is disclosed. The method includes Fin-FET devices with fins that are composed of a first material, and then merged together by epitaxial deposition of a second material. The fins are vertically recesses using a selective etch. A continuous silicide layer is formed over the increased surface areas of the first material and the second material, leading to smaller resistance. A stress liner overlaying the FET device is afterwards deposited. An FET device is also disclosed, which FET device includes a plurality of Fin-FET devices, the fins of which are composed of a first material. The FET device includes a second material, which is epitaxially merging the fins. The fins are vertically recessed relative to an upper surface of the second material. The FET device furthermore includes a continuous silicide layer formed over the fins and over the second material, and a stress liner covering the device. | 11-24-2011 |
20110303915 | Compressively Stressed FET Device Structures - Methods for fabricating FET device structures are disclosed. The methods include receiving a fin of a Si based material, and converting a region of the fin into an oxide element. The oxide element exerts pressure onto the fin where a Fin-FET device is fabricated. The exerted pressure induces compressive stress in the device channel of the Fin-FET device. The methods also include receiving a rectangular member of a Si based material and converting a region of the member into an oxide element. The methods further include patterning the member that N fins are formed in parallel, while being abutted by the oxide element, which exerts pressure onto the N fins. Fin-FET devices are fabricated in the compressed fins, which results in compressively stressed device channels. FET devices structures are also disclosed. An FET devices structure has a Fin-FET device with a fin of a Si based material. An oxide element is abutting the fin and exerts pressure onto the fin. The Fin-FET device channel is compressively stressed due to the pressure on the fin. A further FET device structure has Fin-FET devices in a row each having fins. An oxide element extending perpendicularly to the row of fins is abutting the fins and exerts pressure onto the fins. Device channels of the Fin-FET devices are compressively stressed due to the pressure on the fins. | 12-15-2011 |
20120043610 | Controlled Fin-Merging for Fin Type FET Devices - A method for fabricating FET devices is disclosed. The method includes forming continuous fins of a semiconductor material and fabricating gate structures overlaying the continuous fins. After the fabrication of the gate structures, the method uses epitaxial deposition to merge the continuous fins to one another. Next, the continuous fins are cut into segments. The fabricated FET devices are characterized as being non-planar devices. A placement of non-planar FET devices is also disclosed, which includes non- planar devices that have electrodes, and the electrodes contain fins and an epitaxial layer which merges the fins together. The non-planar devices are so placed that their gate structures are in a parallel configuration separated from one another by a first distance, and the fins of differing non-planar devices line up in essentially straight lines. The electrodes of differing FET devices are separated from one another by a cut defined by opposing facets of the electrodes, with the opposing facets also defining the width of the cut. The width of the cut is smaller than one fifth of the first distance which separates the gate structures. | 02-23-2012 |
20120061762 | Asymmetric FinFET devices - Asymmetric FET devices, and a method for fabricating such asymmetric devices on a fin structure is disclosed. The fabrication method includes disposing over the fin a high-k dielectric layer followed by a threshold-modifying layer, performing an ion bombardment at a tilted angle which removes the threshold-modifying layer over one of the fin's side-surfaces. The completed FET devices will be asymmetric due to the threshold-modifying layer being present only in one of two devices on the side of the fin. In an alternate embodiment further asymmetries are introduced, again using tilted ion implantation, resulting in differing gate-conductor materials for the two FinFET devices on each side of the fin. | 03-15-2012 |
20120112279 | CONTACTS FOR FET DEVICES - A method for contacting an FET device is disclosed. The method includes vertically recessing the device isolation, which exposes a sidewall surface on both the source and the drain. Next, silicidation is performed, resulting in a silicide layer covering both the top surface and the sidewall surface of the source and the drain. Next, metallic contacts are applied in such manner that they engage the silicide layer on both its top and on its sidewall surface. A device characterized as being an FET device structure with enlarged contact areas is also disclosed. The device has a vertically recessed isolation, thereby having an exposed sidewall surface on both the source and the drain. A silicide layer is covering both the top surface and the sidewall surface of both the source and the drain. Metallic contacts to the device engage the silicide on its top surface and on its sidewall surface. | 05-10-2012 |
20120153397 | Stressed Fin-FET Devices with Low Contact Resistance - An FET device includes a plurality of Fin-FET devices. The fins of the Fin-FET devices are composed of a first material. The FET device includes a second material, which is epitaxially merging the fins. The fins are vertically recessed relative to an upper surface of the second material. The FET device furthermore includes a continuous silicide layer formed over the fins and over the second material, and a stress liner covering the device. | 06-21-2012 |
20120223386 | Asymmetric FinFET devices - Asymmetric FET devices, and a method for fabricating such asymmetric devices on a fin structure is disclosed. The fabrication method includes disposing over the fin a high-k dielectric layer followed by a threshold- modifying layer, performing an ion bombardment at a tilted angle which removes the threshold-modifying layer over one of the fin's side-surfaces. The completed FET devices will be asymmetric due to the threshold-modifying layer being present only in one of two devices on the side of the fin. In an alternate embodiment further asymmetries are introduced, again using tilted ion implantation, resulting in differing gate-conductor materials for the two FinFET devices on each side of the fin. | 09-06-2012 |
20120267722 | Compressively Stressed FET Device Structures - An FET device structure has a Fin-FET device with a fin of a Si based material. An oxide element is abutting the fin and exerts pressure onto the fin. The Fin-FET device channel is compressively stressed due to the pressure on the fin. A further FET device structure has Fin-FET devices in a row. An oxide element extending perpendicularly to the row of fins is abutting the fins and exerts pressure onto the fins. Device channels of the Fin-FET devices are compressively stressed due to the pressure on the fins. | 10-25-2012 |
20120276695 | Strained thin body CMOS with Si:C and SiGe stressor - A method is disclosed which is characterized as being process integration of raised source/drain and strained body for ultra thin planar and FinFET CMOS devices. NFET and PFET devices have their source/drain raised by selective epitaxy with in-situ p-type doped SiGe for the PFET device, and in-situ n-type doped Si:C for the NFET device. Such raised source/drains offer low parasitic resistance and they impart a strain onto the device bodies of the correct sign for respective carrier, electron or hole, mobility enhancement. | 11-01-2012 |
20120286329 | SOI FET with embedded stressor block - A method and a structure are disclosed relating to strained body UTSOI FET devices. The method includes forming voids in the source/drain regions that penetrate down into the substrate below the insulating layer. The voids are epitaxially filled with a semiconductor material of a differing lattice constant than the one of the SOI layer, thus becoming a stressor block, and imparts a strain onto the FET device body. | 11-15-2012 |
20120305940 | Defect Free Si:C Epitaxial Growth - A method and structure are disclosed for a defect free Si:C source/drain in an NFET device. A wafer is accepted with a primary surface of {100} crystallographic orientation. A recess is formed in the wafer in such manner that the bottom surface and the four sidewall surfaces of the recess are all having {100} crystallographic orientations. A Si:C material is eptaxially grown in the recess, and due to the crystallographic orientations the defect density next to each of the four sidewall surfaces is essentially the same as next to the bottom surface. The epitaxially filled recess is used in the source/drain fabrication of an NFET device. The NFET device is oriented along the <100> crystallographic direction, and has the device channel under a tensile strain due to the defect free Si:C in the source/drain. | 12-06-2012 |
20120306015 | CONTACTS FOR FET DEVICES - A device characterized as being an FET device structure with enlarged contact areas is disclosed. The device has a vertically recessed isolation, thereby having an exposed sidewall surface on both the source and the drain. A silicide layer is covering both the top surface and the sidewall surface of both the source and the drain. Metallic contacts to the device engage the silicide layer on its top surface and on its sidewall surface. | 12-06-2012 |
20130069171 | Controlled Fin-Merging for Fin Type FET Devices - A placement of non-planar FET devices is disclosed, which includes non-planar devices that have electrodes, and the electrodes contain fins and an epitaxial layer which merges the fins together. The non-planar devices are so placed that their gate structures are in a parallel configuration separated from one another by a first distance, and the fins of differing non-planar devices line up in essentially straight lines. The electrodes of differing FET devices are separated from one another by a cut defined by opposing facets of the electrodes, with the opposing facets also defining the width of the cut. The width of the cut is smaller than one fifth of the first distance which separates the gate structures. | 03-21-2013 |
20130240993 | FULLY-DEPLETED SON - A semiconductor device and a method of fabricating a semiconductor device. The semiconductor device includes a semiconductor substrate, an insulating layer, a first semiconductor layer, a dielectric layer, a second semiconductor layer, a source and drain junction, a gate, and a spacer. The method includes the steps of forming a semiconductor substrate, forming a shallow trench isolation layer, growing a first epitaxial layer, growing a second epitaxial layer, forming a gate, forming a spacer, performing a reactive ion etching, removing a portion of the first epitaxial layer, filling the void with a dielectric, etching back a portion of the dielectric, growing a silicon layer, implanting a source and drain junction, and forming an extension. | 09-19-2013 |
20130249020 | Borderless Contacts for Semiconductor Devices - In one exemplary embodiment of the invention, a method (e.g., to fabricate a semiconductor device having a borderless contact) including: forming a first gate structure on a substrate; depositing an interlevel dielectric over the first gate structure; planarizing the interlevel dielectric to expose a top surface of the first gate structure; removing at least a portion of the first gate structure; forming a second gate structure in place of the first gate structure; forming a contact area for the borderless contact by removing a portion of the interlevel dielectric; and forming the borderless contact by filling the contact area with a metal-containing material. | 09-26-2013 |
20130264641 | ROBUST ISOLATION FOR THIN-BOX ETSOI MOSFETS - A thin BOX ETSOI device with robust isolation and method of manufacturing. The method includes providing a wafer with at least a pad layer overlying a first semiconductor layer overlying an oxide layer overlying a second semiconductor layer, wherein the first semiconductor layer has a thickness of 10 nm or less. The process continues with etching a shallow trench into the wafer, extending partially into the second semiconductor layer and forming first spacers on the sidewalls of said shallow trench. After spacer formation, the process continues by etching an area directly below and between the first spacers, exposing the underside of the first spacers, forming second spacers covering all exposed portions of the first spacers, wherein the pad oxide layer is removed, and forming a gate structure over the first semiconductor wafer. | 10-10-2013 |
20130270627 | FinFET NON-VOLATILE MEMORY AND METHOD OF FABRICATION - A method of manufacturing a FinFET non-volatile memory device and a FinFET non-volatile memory device structure. A substrate is provided and a layer of semiconductor material is deposited over the substrate. A hard mask is deposited over the semiconductor material and the structure is patterned to form fins. A charge storage layer is deposited over the structure, including the fins and the portions of it are damaged using an angled ion implantation process. The damaged portions are removed and gate structures are formed on either side of the fin, with only one side having a charge storage layer. | 10-17-2013 |
20130337621 | NON-RELAXED EMBEDDED STRESSORS WITH SOLID SOURCE EXTENSION REGIONS IN CMOS DEVICES - A method of forming a field effect transistor (FET) device includes forming a patterned gate structure over a substrate; forming a solid source dopant material on the substrate, adjacent sidewall spacers of the gate structure; performing an anneal process at a temperature sufficient to cause dopants from the solid source dopant material to diffuse within the substrate beneath the gate structure and form source/drain extension regions; following formation of the source/drain extension regions, forming trenches in the substrate adjacent the sidewall spacers, corresponding to source/drain regions; and forming an embedded semiconductor material in the trenches so as to provide a stress on a channel region of the substrate defined beneath the gate structure. | 12-19-2013 |
20140042521 | MOSFET WITH RECESSED CHANNEL FILM AND ABRUPT JUNCTIONS - MOSFETs and methods for making MOSFETs with a recessed channel and abrupt junctions are disclosed. The method includes creating source and drain extensions while a dummy gate is in place. The source/drain extensions create a diffuse junction with the silicon substrate. The method continues by removing the dummy gate and etching a recess in the silicon substrate. The recess intersects at least a portion of the source and drain junction. Then a channel is formed by growing a silicon film to at least partially fill the recess. The channel has sharp junctions with the source and drains, while the unetched silicon remaining below the channel has diffuse junctions with the source and drain. Thus, a MOSFET with two junction regions, sharp and diffuse, in the same transistor can be created. | 02-13-2014 |
20140042542 | MOSFET WITH RECESSED CHANNEL FILM AND ABRUPT JUNCTIONS - MOSFETs and methods for making MOSFETs with a recessed channel and abrupt junctions are disclosed. The method includes creating source and drain extensions while a dummy gate is in place. The source/drain extensions create a diffuse junction with the silicon substrate. The method continues by removing the dummy gate and etching a recess in the silicon substrate. The recess intersects at least a portion of the source and drain junction. Then a channel is formed by growing a silicon film to at least partially fill the recess. The channel has sharp junctions with the source and drains, while the unetched silicon remaining below the channel has diffuse junctions with the source and drain. Thus, a MOSFET with two junction regions, sharp and diffuse, in the same transistor can be created. | 02-13-2014 |
20140042543 | MOSFET WITH RECESSED CHANNEL FILM AND ABRUPT JUNCTIONS - MOSFETs and methods for making MOSFETs with a recessed channel and abrupt junctions are disclosed. The method includes creating source and drain extensions while a dummy gate is in place. The source/drain extensions create a diffuse junction with the silicon substrate. The method continues by removing the dummy gate and etching a recess in the silicon substrate. The recess intersects at least a portion of the source and drain junction. Then a channel is formed by growing a silicon film to at least partially fill the recess. The channel has sharp junctions with the source and drains, while the unetched silicon remaining below the channel has diffuse junctions with the source and drain. Thus, a MOSFET with two junction regions, sharp and diffuse, in the same transistor can be created. | 02-13-2014 |
20140084372 | DUAL SHALLOW TRENCH ISOLATION LINER FOR PREVENTING ELECTRICAL SHORTS - A shallow trench is formed to extend into a handle substrate of a semiconductor-on-insulator (SOI) layer. A dielectric liner stack of a dielectric metal oxide layer and a silicon nitride layer is formed in the shallow trench, followed by deposition of a shallow trench isolation fill portion. The dielectric liner stack is removed from above a top surface of a top semiconductor portion, followed by removal of a silicon nitride pad layer and an upper vertical portion of the dielectric metal oxide layer. A divot laterally surrounding a stack of a top semiconductor portion and a buried insulator portion is filled with a silicon nitride portion. Gate structures and source/drain structures are subsequently formed. The silicon nitride portion or the dielectric metal oxide layer functions as a stopping layer during formation of source/drain contact via holes, thereby preventing electrical shorts between source/drain contact via structures and the handle substrate. | 03-27-2014 |
20140099773 | DUAL SHALLOW TRENCH ISOLATION LINER FOR PREVENTING ELECTRICAL SHORTS - A shallow trench is formed to extend into a handle substrate of a semiconductor-on-insulator (SOI) layer. A dielectric liner stack of a dielectric metal oxide layer and a silicon nitride layer is formed in the shallow trench, followed by deposition of a shallow trench isolation fill portion. The dielectric liner stack is removed from above a top surface of a top semiconductor portion, followed by removal of a silicon nitride pad layer and an upper vertical portion of the dielectric metal oxide layer. A divot laterally surrounding a stack of a top semiconductor portion and a buried insulator portion is filled with a silicon nitride portion. Gate structures and source/drain structures are subsequently formed. The silicon nitride portion or the dielectric metal oxide layer functions as a stopping layer during formation of source/drain contact via holes, thereby preventing electrical shorts between source/drain contact via structures and the handle substrate. | 04-10-2014 |
20140124845 | Method and Structure for Forming On-Chip High Quality Capacitors With ETSOI Transistors - An ETSOI transistor and a capacitor are formed respectively in a transistor and capacitor region thereof by etching through an ETSOI and thin BOX layers in a replacement gate HK/MG flow. The capacitor formation is compatible with an ETSOI replacement gate CMOS flow. A low resistance capacitor electrode makes it possible to obtain a high quality capacitor or varactor. The lack of topography during dummy gate patterning are achieved by lithography in combination of which is accompanied with appropriate etch. | 05-08-2014 |
20140124862 | STRUCTURE AND METHOD TO IMPROVE ETSOI MOSFETS WITH BACK GATE - A structure to improve ETSOI MOSFET devices includes a wafer having regions with at least a first semiconductor layer overlying an oxide layer overlying a second semiconductor layer. The regions are separated by a STI which extends at least partially into the second semiconductor layer and is partially filled with a dielectric. A gate structure is formed over the first semiconductor layer and during the wet cleans involved, the STI divot erodes until it is at a level below the oxide layer. Another dielectric layer is deposited over the device and a hole is etched to reach source and drain regions. The hole is not fully landed, extending at least partially into the STI, and an insulating material is deposited in the hole. | 05-08-2014 |
20140273418 | BACK-GATED SUBSTRATE AND SEMICONDUCTOR DEVICE, AND RELATED METHOD OF FABRICATION - A method of forming a semiconductor device is disclosed. The method includes forming a set of doped regions in a substrate; forming a crystalline dielectric layer on the substrate, the crystalline dielectric layer including an epitaxial oxide; forming a semiconductor layer on the crystalline dielectric layer, the semiconductor layer and the crystalline dielectric layer forming an extremely thin semiconductor-on-insulator (ETSOI) structure; and forming a set of devices on the semiconductor layer, wherein at least one device in the set of devices is formed over a doped region. | 09-18-2014 |
20140302661 | CONTACT ISOLATION SCHEME FOR THIN BURIED OXIDE SUBSTRATE DEVICES - A method of forming a semiconductor-on-insulator (SOI) device includes defining a shallow trench isolation (STI) structure in an SOI substrate, the SOI substrate including a bulk layer, a buried insulator (BOX) layer over the bulk layer, and an SOI layer over the BOX layer; forming a doped region in a portion of the bulk layer corresponding to a lower location of the STI structure, the doped region extending laterally into the bulk layer beneath the BOX layer; selectively etching the doped region of the bulk layer with respect to undoped regions of the bulk layer such that the lower location of the STI structure undercuts the BOX layer; and filling the STI structure with an insulator fill material. | 10-09-2014 |
20140308808 | Replacement Gate Integration Scheme Employing Multiple Types of Disposable Gate Structures - A plurality of disposable gate materials is employed to form multiple types of disposable gate stack structures. Different types of disposable gate stack structures are sequentially removed and replaced with different types of replacement gate stack structures. Sequential removal of the different types of disposable gate stack structures can be effected by employing etch chemistries that remove one type of disposable gate material while not etching at least another type of disposable gate material. Different types of replacement gate stack structures can employ different work function materials. Lithographic patterning of workfunction materials is avoided, and each replacement gate stack structure can have a workfunction material portion having a uniform thickness. | 10-16-2014 |
20140332903 | Integrated Circuit Having Raised Source Drains Devices with Reduced Silicide Contact Resistance and Methods to Fabricate Same - A structure has at least one field effect transistor having a gate stack disposed between raised source drain structures that are adjacent to the gate stack. The gate stack and raised source drain structures are disposed on a surface of a semiconductor material. The structure further includes a layer of field dielectric overlying the gate stack and raised source drain structures and first contact metal and second contact metal extending through the layer of field dielectric. The first contact metal terminates in a first trench formed through a top surface of a first raised source drain structure, and the second contact metal terminates in a second trench formed through a top surface of a second raised source drain structure. Each trench has silicide formed on sidewalls and a bottom surface of at least a portion of the trench. Methods to fabricate the structure are also disclosed. | 11-13-2014 |
20140339638 | INTEGRATING CHANNEL SIGE INTO PFET STRUCTURES - A structure including nFET and pFET devices is fabricated by depositing a germanium-containing layer on a crystalline silicon layer. The crystalline silicon layer is converted to silicon germanium in the pFET region to provide a thin silicon germanium channel for the pFET device fabricated thereon. Silicon trench isolation is provided subsequent to deposition of the germanium-containing layer. There is substantially no thickness variation in the silicon germanium layer across the pFET device width. Electrical degradation near the shallow trench isolation region bounding the pFET device is accordingly avoided. Shallow trench isolation may be provided prior to or after conversion of the silicon layer to silicon germanium in the pFET region. The germanium-containing layer is removed from the nFET region so that an nFET device can be formed on the crystalline silicon layer. | 11-20-2014 |
20140349459 | Integrated Circuit Having Raised Source Drains Devices with Reduced Silicide Contact Resistance and Methods to Fabricate Same - A structure has at least one field effect transistor having a gate stack disposed between raised source drain structures that are adjacent to the gate stack. The gate stack and raised source drain structures are disposed on a surface of a semiconductor material. The structure further includes a layer of field dielectric overlying the gate stack and raised source drain structures and first contact metal and second contact metal extending through the layer of field dielectric. The first contact metal terminates in a first trench formed through a top surface of a first raised source drain structure, and the second contact metal terminates in a second trench formed through a top surface of a second raised source drain structure. Each trench has silicide formed on sidewalls and a bottom surface of at least a portion of the trench. Methods to fabricate the structure are also disclosed. | 11-27-2014 |
20140353801 | DEVICE ISOLATION IN FINFET CMOS - Embodiments herein provide approaches for device isolation in a complimentary metal-oxide fin field effect transistor. Specifically, a semiconductor device is formed with a retrograde doped layer over a substrate to minimize a source to drain punch-through leakage. A set of replacement fins is formed over the retrograde doped layer, each of the set of replacement fins comprising a high mobility channel material (e.g., silicon, or silicon-germanium). The retrograde doped layer may be formed using an in situ doping process or a counter dopant retrograde implant. The device may further include a carbon liner positioned between the retrograde doped layer and the set of replacement fins to prevent carrier spill-out to the replacement fins. | 12-04-2014 |
20140361377 | RETROGRADE DOPED LAYER FOR DEVICE ISOLATION - Embodiments herein provide device isolation in a complimentary metal-oxide fin field effect transistor. Specifically, a semiconductor device is formed with a retrograde doped layer over a substrate to minimize a source to drain punch-through leakage. A set of high mobility channel fins is formed over the retrograde doped layer, each of the set of high mobility channel fins comprising a high mobility channel material (e.g., silicon or silicon-germanium). The retrograde doped layer may be formed using an in situ doping process or a counter dopant retrograde implant. The device may further include a carbon liner positioned between the retrograde doped layer and the set of high mobility channel fins to prevent carrier spill-out to the high mobility channel fins. | 12-11-2014 |
20140367752 | TRANSISTOR HAVING ALL-AROUND SOURCE/DRAIN METAL CONTACT CHANNEL STRESSOR AND METHOD TO FABRICATE SAME - An intermediate transistor structure includes a fin structure disposed on a surface of an insulating layer. The fin structure has a gate structure disposed thereon between first and second ends of the fin structure. A first portion of the fin structure is a first doped portion that is disposed over a first recess in the surface of the insulating layer and a second portion of the fin structure is a second doped portion disposed over a second recess in the surface of the insulating layer. The intermediate transistor structure further includes source and drain metal disposed around the first and second doped portions, each inducing one of compression strain or tensile strain in a portion of the fin structure that is disposed within the gate structure and that functions during operation of the transistor as a channel of the transistor. | 12-18-2014 |
20140367781 | LATERAL DIODE COMPATIBLE WITH FINFET AND METHOD TO FABRICATE SAME - A method to fabricate a diode device includes providing a fin structure formed in a SOI layer. The fin structure has a sacrificial gate structure disposed on the fin structure between a first end of the fin structure and a second end of the fin structure. The method further includes depositing first doped semiconductor material on the first and second ends of the fin structure, where the first doped semiconductor material on the first end of the fin structure has one of the same doping polarity or an opposite doping polarity as the first doped semiconductor material on the second end of the fin structure. The method further includes removing the sacrificial gate structure to form a gap between the deposited first doped semiconductor material; depositing a second doped semiconductor material within the gap and forming first and second electrical contacts conductively connected to the first doped semiconductor material. | 12-18-2014 |
20140367782 | Lateral Diode Compatible with FinFET and Method to Fabricate Same - A structure includes a fin having first end and second ends and a substantially intrinsic portion between the first and second ends. The structure further includes a first region of doped semiconductor material disposed on the first end of the fin and a second region of doped semiconductor material disposed on the second end of the fin. The first region has one of the same doping polarity or an opposite doping polarity as the second region. The structure also includes a third region of doped semiconductor material disposed on the intermediate portion of the fin adjacent to the first region and the second region. The third region has a doping polarity that differs from the doping polarity of at least one of the first and second regions and forms a p-n junction with the at least one of the first and second regions. | 12-18-2014 |
20140374807 | METHOD OF DEVICE ISOLATION IN CLADDING Si THROUGH IN SITU DOPING - Aspects of the present invention relate to an approach for forming an integrated circuit having a set of fins on a silicon substrate, with the set of fins being formed according to a predetermined pattern. In situ doping of the fins with an N-type dopant prior to deposition of an epitaxial layer minimizes punch through leakage whilst an epitaxial depositional process applies a cladding layer on the doped fins, the deposition resulting in a multigate device having improved device isolation. | 12-25-2014 |
20150021690 | FIN TRANSFORMATION PROCESS AND ISOLATION STRUCTURES FACILITATING DIFFERENT FIN ISOLATION SCHEMES - Methods and semiconductor structures formed from the methods are provided which facilitate fabricating semiconductor fin structures. The methods include, for example: providing a wafer with at least one semiconductor fin extending above a substrate; transforming a portion of the semiconductor fin(s) into an isolation layer, the isolation layer separating a semiconductor layer of the semiconductor fin(s) from the substrate; and proceeding with forming a fin device(s) of a first architectural type in a first fin region of the semiconductor fin(s), and a fin device(s) of a second architectural type in a second fin region of the semiconductor fin(s), where the first architectural type and the second architectural type are different fin device architectures. | 01-22-2015 |
20150024572 | PROCESS FOR FACILTIATING FIN ISOLATION SCHEMES - Semiconductor fabrication methods are provided which include facilitating fabricating semiconductor fin structures by: providing a wafer with at least one fin extending above a substrate, the at least one fin including a first layer disposed above a second layer; mechanically stabilizing the first layer; removing at least a portion of the second layer of the fin(s) to create a void below the first layer; filling the void, at least partially, below the first layer with an isolation material to create an isolation layer within the fin(s); and proceeding with forming a fin device(s) of a first architectural type in a first fin region of the fin(s), and a fin device(s) of a second architectural type in a second fin region of the fin(s), where the first architectural type and the second architectural type are different fin device architectures. | 01-22-2015 |
20150041856 | Compound Semiconductor Integrated Circuit and Method to Fabricate Same - A structure includes a substrate having a surface and a first transistor disposed in a first region supported by the surface of the substrate. The first transistor has a channel formed in a first compound (Group III-V) semiconductor having a first energy bandgap. The structure further includes a second transistor disposed in a second region supported by the substrate. The second transistor has a channel formed in a second compound (Group III-V) semiconductor having a second energy bandgap that is larger than the first energy bandgap. In one embodiment the first compound semiconductor is a layer that overlies a first portion of the surface of the substrate and the substrate is the second compound semiconductor. In another embodiment the second compound semiconductor is provided as a second layer that overlies a second portion of the surface of the substrate. | 02-12-2015 |
20150041908 | METHOD OF MANUFACTURING A FinFET DEVICE USING A SACRIFICIAL EPITAXY REGION FOR IMPROVED FIN MERGE AND FinFET DEVICE FORMED BY SAME - A method for manufacturing a fin field-effect transistor (FinFET) device comprises forming a plurality of fins on a substrate, epitaxially growing a sacrificial epitaxy region between the fins, stopping growth of the sacrificial epitaxy region at a beginning of merging of epitaxial shapes between neighboring fins, and forming a dielectric layer on the substrate including the fins and the sacrificial epitaxy region, wherein a portion of the dielectric layer is positioned between the sacrificial epitaxy region extending from fins of adjacent transistors. | 02-12-2015 |
20150044859 | COMPOUND SEMICONDUCTOR INTEGRATED CIRCUIT AND METHOD TO FABRICATE SAME - A structure includes a substrate having a surface and a first transistor disposed in a first region supported by the surface of the substrate. The first transistor has a channel formed in a first compound (Group III-V) semiconductor having a first energy bandgap. The structure further includes a second transistor disposed in a second region supported by the substrate. The second transistor has a channel formed in a second compound (Group III-V) semiconductor having a second energy bandgap that is larger than the first energy bandgap. In one embodiment the first compound semiconductor is a layer that overlies a first portion of the surface of the substrate and the substrate is the second compound semiconductor. In another embodiment the second compound semiconductor is provided as a second layer that overlies a second portion of the surface of the substrate. Methods to form the structure are also disclosed. | 02-12-2015 |
20150061010 | STRUCTURE FOR IMPROVED CONTACT RESISTANCE AND EXTENSION DIFFUSION CONTROL - Semiconductor structures are provided including a raised source region comprising, from bottom to top, a source-side phosphorus doped epitaxial semiconductor material portion and a source-side arsenic doped epitaxial semiconductor material portion and located on one side of a gate structure, and a raised drain region comprising from bottom to top, a drain-side phosphorus doped epitaxial semiconductor material portion and a drain-side arsenic doped epitaxial semiconductor material portion and located on another side of the gate structure. | 03-05-2015 |
20150061021 | SEMI-CONDUCTOR DEVICE WITH EPITAXIAL SOURCE/DRAIN FACETTING PROVIDED AT THE GATE EDGE - A semiconductor structure includes an active layer located on a substrate and a first and a second gate structure located on the active layer. A first raised epitaxial region is located on the active layer between the first and the second gate. The first raised epitaxial region has a first facet shaped edge and a first vertical shape edge, such that the first facet shaped edge is located adjacent the first gate structure. A second raised epitaxial region is also located on the active layer between the first and the second gate structure. The second raised epitaxial region has a second facet shaped edge and a second vertical shape edge, such that the second facet shaped edge is located adjacent the second gate structure. A trench region is located between the first and the second vertical shaped edge for electrically isolating the first and the second raised epitaxial region. | 03-05-2015 |
20150061076 | HIGH DENSITY RESISTOR - At least one three dimensional semiconductor fin is formed from a top semiconductor material of a substrate. A dielectric material is formed along vertical sidewalls and an upper surface of the at least one three dimensional semiconductor fin. A polysilicon resistor is formed on exposed surfaces of the dielectric material and surrounding the at least one semiconductor fin. An interconnect dielectric material is formed above the polysilicon resistor. The interconnect dielectric material has at least one contact structure that extends through the interconnect dielectric to an upper surface of the polysilicon resistor. | 03-05-2015 |
20150069521 | NANOWIRE COMPATIBLE E-FUSE - An e-fuse is provided in one area of a semiconductor substrate. The E-fuse includes a vertical stack of from, bottom to top, base metal semiconductor alloy portion, a first metal semiconductor alloy portion, a second metal semiconductor portion, a third metal semiconductor alloy portion and a fourth metal semiconductor alloy portion, wherein the first metal semiconductor alloy portion and the third metal semiconductor portion have outer edges that are vertically offset and do not extend beyond vertical edges of the second metal semiconductor alloy portion and the fourth metal semiconductor alloy portion. | 03-12-2015 |
20150083999 | Gate-All-Around Nanowire MOSFET and Method of Formation - A method for fabricating a semiconductor device comprises forming a nanowire on an insulator layer at a surface of a substrate; forming a dummy gate over a portion of the nanowire and a portion of the insulator layer; forming recesses in the insulator layer on opposing sides of the dummy gate; forming spacers on opposing sides of the dummy gate; forming source regions and drain regions in the recesses in the insulator layer on opposing sides of the dummy gate; depositing an interlayer dielectric on the source regions and the drain regions; removing the dummy gate to form a trench; removing the insulator layer under the nanowire such that a width of the trench underneath the nanowire is equal to or less than a distance between the spacers; and forming a replacement gate in the trench. | 03-26-2015 |
20150084001 | GATE-ALL-AROUND NANOWIRE MOSFET AND METHOD OF FORMATION - A method for fabricating a semiconductor device comprises forming a nanowire on an insulator layer at a surface of a substrate; forming a dummy gate over a portion of the nanowire and a portion of the insulator layer; forming recesses in the insulator layer on opposing sides of the dummy gate; forming spacers on opposing sides of the dummy gate; forming source regions and drain regions in the recesses in the insulator layer on opposing sides of the dummy gate; depositing an interlayer dielectric on the source regions and the drain regions; removing the dummy gate to form a trench; removing the insulator layer under the nanowire such that a width of the trench underneath the nanowire is equal to or less than a distance between the spacers; and forming a replacement gate in the trench. | 03-26-2015 |