Patent application number | Description | Published |
20110031503 | DEVICE WITH STRESSED CHANNEL - An FET device is disclosed which contains a source and a drain that are each provided with an extension. The source and the drain, and their extensions, are composed of epitaxial materials containing Ge or C. The epitaxial materials and the Si substrate have differing lattice constants, consequently the source and the drain and their extensions are imparting a state of stress onto the channel. For a PFET device the epitaxial material may be SiGe, or Ge, and the channel may be in a compressive state of stress. For an NFET device the epitaxial material may be SiC and the channel may be in a tensile state of stress. A method for fabricating an FET device is also disclosed. One may form a first recession in the Si substrate to a first depth on opposing sides of the gate. The first recession is filled epitaxially with a first epitaxial material. Then, a second recession may be formed in the Si substrate to a second depth, which is greater than the first depth. Next, one may fill the second recession with a second epitaxial material, which is the same kind of material as the first epitaxial material. The epitaxial materials are selected to have a different lattice constant than the Si substrate, and consequently a state of stress is being imparted onto the channel. | 02-10-2011 |
20110309333 | SEMICONDUCTOR DEVICES FABRICATED BY DOPED MATERIAL LAYER AS DOPANT SOURCE - A method of forming a semiconductor device is provided, in which the dopant for the source and drain regions is introduced from a doped dielectric layer. In one example, a gate structure is formed on a semiconductor layer of an SOI substrate, in which the thickness of the semiconductor layer is less than 10 nm. A doped dielectric layer is formed over at least the portion of the semiconductor layer that is adjacent to the gate structure. The dopant from the doped dielectric layer is driven into the portion of the semiconductor layer that is adjacent to the gate structure. The dopant diffused into the semiconductor provides source and drain extension regions. | 12-22-2011 |
20120032275 | METAL SEMICONDUCTOR ALLOY STRUCTURE FOR LOW CONTACT RESISTANCE - Contact via holes are etched in a dielectric material layer overlying a semiconductor layer to expose the topmost surface of the semiconductor layer. The contact via holes are extended into the semiconductor material layer by continuing to etch the semiconductor layer so that a trench having semiconductor sidewalls is formed in the semiconductor material layer. A metal layer is deposited over the dielectric material layer and the sidewalls and bottom surface of the trench. Upon an anneal at an elevated temperature, a metal semiconductor alloy region is formed, which includes a top metal semiconductor alloy portion that includes a cavity therein and a bottom metal semiconductor alloy portion that underlies the cavity and including a horizontal portion. A metal contact via is formed within the cavity so that the top metal semiconductor alloy portion laterally surrounds a bottom portion of a bottom portion of the metal contact via. | 02-09-2012 |
20120040522 | METHOD FOR INTEGRATING MULTIPLE THRESHOLD VOLTAGE DEVICES FOR CMOS - A method to achieve multiple threshold voltage (Vt) devices on the same semiconductor chip is disclosed. The method provides different threshold voltage devices using threshold voltage adjusting materials and a subsequent drive in anneal instead of directly doping the channel. As such, the method of the present disclosure avoids short channel penalties. Additionally, no ground plane/back gates are utilized in the present application thereby the method of the present disclosure can be easily integrated into current complementary metal oxide semiconductor (CMOS) processing technology. | 02-16-2012 |
20120126295 | BORDERLESS CONTACT FOR REPLACEMENT GATE EMPLOYING SELECTIVE DEPOSITION - A self-aligned gate cap dielectric can be employed to form a self-aligned contact to a diffusion region, while preventing electrical short with a gate conductor due to overlay variations. In one embodiment, an electroplatable or electrolessly platable metal is selectively deposited on conductive materials in a gate electrode, while the metal is not deposited on dielectric surfaces. The metal portion on top of the gate electrode is converted into a gate cap dielectric including the metal and oxygen. In another embodiment, a self-assembling monolayer is formed on dielectric surfaces, while exposing metallic top surfaces of a gate electrode. A gate cap dielectric including a dielectric oxide is formed on areas not covered by the self-assembling monolayer. The gate cap dielectric functions as an etch-stop structure during formation of a via hole, so that electrical shorting between a contact via structure formed therein and the gate electrode is avoided. | 05-24-2012 |
20120187482 | FABRICATION OF CMOS TRANSISTORS HAVING DIFFERENTIALLY STRESSED SPACERS - CMOS transistors are formed incorporating a gate electrode having tensely stressed spacers on the gate sidewalls of an n channel field effect transistor and having compressively stressed spacers on the gate sidewalls of a p channel field effect transistor to provide differentially stressed channels in respective transistors to increase carrier mobility in the respective channels. | 07-26-2012 |
20120187523 | METHOD AND STRUCTURE FOR SHALLOW TRENCH ISOLATION TO MITIGATE ACTIVE SHORTS - A shallow trench isolation region is provided in which void formation is substantially or totally eliminated therefrom. The shallow trench isolation mitigates active shorts between two active regions of a semiconductor substrate. The shallow trench isolation region includes a bilayer liner which is present on sidewalls and a bottom wall of a trench that is formed in a semiconductor substrate. The bilayer liner of the present disclosure includes, from bottom to top, a shallow trench isolation liner, e.g., a semiconductor oxide and/or nitride, and a high k liner, e.g., a dielectric material having a dielectric constant that is greater than silicon oxide. | 07-26-2012 |
20120256260 | DUAL-DEPTH SELF-ALIGNED ISOLATION STRUCTURE FOR A BACK GATE ELECTRODE - Doped semiconductor back gate regions self-aligned to active regions are formed by first patterning a top semiconductor layer and a buried insulator layer to form stacks of a buried insulator portion and a semiconductor portion. Oxygen is implanted into an underlying semiconductor layer at an angle so that oxygen-implanted regions are formed in areas that are not shaded by the stack or masking structures thereupon. The oxygen implanted portions are converted into deep trench isolation structures that are self-aligned to sidewalls of the active regions, which are the semiconductor portions in the stacks. Dopant ions are implanted into the portions of the underlying semiconductor layer between the deep trench isolation structures to form doped semiconductor back gate regions. A shallow trench isolation structure is formed on the deep trench isolation structures and between the stacks. | 10-11-2012 |
20120280290 | LOCAL INTERCONNECT STRUCTURE SELF-ALIGNED TO GATE STRUCTURE - A common cut mask is employed to define a gate pattern and a local interconnect pattern so that local interconnect structures and gate structures are formed with zero overlay variation relative to one another. A local interconnect structure may be laterally spaced from a gate structure in a first horizontal direction, and contact another gate structure in a second horizontal direction that is different from the first horizontal direction. Further, a gate structure may be formed to be collinear with a local interconnect structure that adjoins the gate structure. The local interconnect structures and the gate structures are formed by a common damascene processing step so that the top surfaces of the gate structures and the local interconnect structures are coplanar with each other. | 11-08-2012 |
20120292705 | SEMICONDUCTOR STRUCTURE HAVING UNDERLAPPED DEVICES - A semiconductor structure which includes a semiconductor on insulator (SOI) substrate. The SOI substrate includes a base semiconductor layer; a buried oxide (BOX) layer in contact with the base semiconductor layer; and an SOI layer in contact with the BOX layer. The semiconductor structure further includes a circuit formed with respect to the SOI layer, the circuit including an N type field effect transistor (NFET) having source and drain extensions in the SOI layer and a gate; and a P type field effect transistor (PFET) having source and drain extensions in the SOI layer and a gate. There may also be a well under each of the NFET and PFET. There is a nonzero electrical bias being applied to the. SOI substrate. One of the NFET extensions and PFET extensions may be underlapped with respect to the NFET gate or PFET gate, respectively. | 11-22-2012 |
20120326241 | METAL SEMICONDUCTOR ALLOY STRUCTURE FOR LOW CONTACT RESISTANCE - Contact via holes are etched in a dielectric material layer overlying a semiconductor layer to expose the topmost surface of the semiconductor layer. The contact via holes are extended into the semiconductor material layer by continuing to etch the semiconductor layer so that a trench having semiconductor sidewalls is formed in the semiconductor material layer. A metal layer is deposited over the dielectric material layer and the sidewalls and bottom surface of the trench. Upon an anneal at an elevated temperature, a metal semiconductor alloy region is formed, which includes a top metal semiconductor alloy portion that includes a cavity therein and a bottom metal semiconductor alloy portion that underlies the cavity and including a horizontal portion. A metal contact via is formed within the cavity so that the top metal semiconductor alloy portion laterally surrounds a bottom portion of a bottom portion of the metal contact via. | 12-27-2012 |
20130001706 | Method and Structure for Low Resistive Source and Drain Regions in a Replacement Metal Gate Process Flow - In one embodiment a method is provided that includes providing a structure including a semiconductor substrate having at least one device region located therein, and a doped semiconductor layer located on an upper surface of the semiconductor substrate in the at least one device region. After providing the structure, a sacrificial gate region having a spacer located on sidewalls thereof is formed on an upper surface of the doped semiconductor layer. A planarizing dielectric material is then formed and the sacrificial gate region is removed to form an opening that exposes a portion of the doped semiconductor layer. The opening is extended to an upper surface of the semiconductor substrate and then an anneal is performed that causes outdiffusion of dopant from remaining portions of the doped semiconductor layer forming a source region and a drain region in portions of the semiconductor substrate that are located beneath the remaining portions of the doped semiconductor layer. A high k gate dielectric and a metal gate are then formed into the extended opening. | 01-03-2013 |
20130015509 | LOW RESISTANCE SOURCE AND DRAIN EXTENSIONS FOR ETSOIAANM Haran; Balasubramanian S.AACI WatervlietAAST NYAACO USAAGP Haran; Balasubramanian S. Watervliet NY USAANM Jagannathan; HemanthAACI GuilderlandAAST NYAACO USAAGP Jagannathan; Hemanth Guilderland NY USAANM Kanakasabapathy; Sivananda K.AACI NiskayunaAAST NYAACO USAAGP Kanakasabapathy; Sivananda K. Niskayuna NY USAANM Mehta; SanjayAACI NiskayunaAAST NYAACO USAAGP Mehta; Sanjay Niskayuna NY US - A gate dielectric is patterned after formation of a first gate spacer by anisotropic etch of a conformal dielectric layer to minimize overetching into a semiconductor layer. In one embodiment, selective epitaxy is performed to sequentially form raised epitaxial semiconductor portions, a disposable gate spacer, and raised source and drain regions. The disposable gate spacer is removed and ion implantation is performed into exposed portions of the raised epitaxial semiconductor portions to form source and drain extension regions. In another embodiment, ion implantation for source and drain extension formation is performed through the conformal dielectric layer prior to an anisotropic etch that forms the first gate spacer. The presence of the raised epitaxial semiconductor portions or the conformation dielectric layer prevents complete amorphization of the semiconductor material in the source and drain extension regions, thereby enabling regrowth of crystalline source and drain extension regions. | 01-17-2013 |
20130015512 | LOW RESISTANCE SOURCE AND DRAIN EXTENSIONS FOR ETSOI - A gate dielectric is patterned after formation of a first gate spacer by anisotropic etch of a conformal dielectric layer to minimize overetching into a semiconductor layer. In one embodiment, selective epitaxy is performed to sequentially form raised epitaxial semiconductor portions, a disposable gate spacer, and raised source and drain regions. The disposable gate spacer is removed and ion implantation is performed into exposed portions of the raised epitaxial semiconductor portions to form source and drain extension regions. In another embodiment, ion implantation for source and drain extension formation is performed through the conformal dielectric layer prior to an anisotropic etch that forms the first gate spacer. The presence of the raised epitaxial semiconductor portions or the conformation dielectric layer prevents complete amorphization of the semiconductor material in the source and drain extension regions, thereby enabling regrowth of crystalline source and drain extension regions. | 01-17-2013 |
20130017680 | METHOD OF IMPROVING REPLACEMENT METAL GATE FILLAANM Haran; Balasubramanian S.AACI WatervlietAAST NYAACO USAAGP Haran; Balasubramanian S. Watervliet NY USAANM Demarest; James J.AACI RensselaerAAST NYAACO USAAGP Demarest; James J. Rensselaer NY US - A method of making a gate of a field effect transistor (FET) with improved fill by a replacement gate process using a sacrificial film includes providing a substrate with a dummy gate. It further includes depositing a sacrificial layer and an encapsulating layer over the substrate, and planarizing so that the encapsulating layer, sacrificial layer and dummy gate are co-planar. The encapsulating layer and a portion of the sacrificial film are removed to leave a remaining sacrificial film. The dummy gate is removed to form and opening in the remaining sacrificial film and to expose sidewalls of the film. Spacers are formed on the sidewalls. A high dielectric constant film and metal film are deposited in the opening and planarized to form a gate. The remaining sacrificial film is removed. The method can be used on planar FETs as well non-planar FETs. | 01-17-2013 |
20130026570 | BORDERLESS CONTACT FOR ULTRA-THIN BODY DEVICES - After formation of a semiconductor device on a semiconductor-on-insulator (SOI) layer, a first dielectric layer is formed over a recessed top surface of a shallow trench isolation structure. A second dielectric layer that can be etched selective to the first dielectric layer is deposited over the first dielectric layer. A contact via hole for a device component located in or on a top semiconductor layer is formed by an etch. During the etch, the second dielectric layer is removed selective to the first dielectric layer, thereby limiting overetch into the first dielectric layer. Due to the etch selectivity, a sufficient amount of the first dielectric layer is present between the bottom of the contact via hole and a bottom semiconductor layer, thus providing electrical isolation for the ETSOI device from the bottom semiconductor layer. | 01-31-2013 |
20130032876 | Replacement Gate ETSOI with Sharp Junction - A transistor structure includes a channel disposed between a source and a drain; a gate conductor disposed over the channel and between the source and the drain; and a gate dielectric layer disposed between the gate conductor and the source, the drain and the channel. In the transistor structure a lower portion of the source and a lower portion of the drain that are adjacent to the channel are disposed beneath and in contact with the gate dielectric layer to define a sharply defined source-drain extension region. Also disclosed is a replacement gate method to fabricate the transistor structure. | 02-07-2013 |
20130034938 | REPLACEMENT GATE ETSOI WITH SHARP JUNCTION - A method includes providing a silicon-on-insulator wafer (e.g., an ETSOI wafer); forming a sacrificial gate structure that overlies a sacrificial insulator layer; forming raised source/drains adjacent to the sacrificial gate structure; depositing a layer that covers the raised source/drains and that surrounds the sacrificial gate structure; and removing the sacrificial gate structure leaving an opening that extends to the sacrificial insulator layer. The method further includes widening the opening so as to expose some of the raised source/drains, removing the sacrificial insulator layer and forming a spacer layer on sidewalls of the opening, the spacer layer covering only an upper portion of the exposed raised source/drains, and depositing a layer of gate dielectric material within the opening. A gate conductor is deposited within the opening. | 02-07-2013 |
20130082311 | SEMICONDUCTOR DEVICES WITH RAISED EXTENSIONS - Transistor devices and methods of their fabrication are disclosed. In one method, a dummy gate structure is formed on a substrate. Bottom portions of the dummy gate structure are undercut. In addition, stair-shaped, raised source and drain regions are formed on the substrate and within at least one undercut formed by the undercutting. The dummy gate structure is removed and a replacement gate is formed on the substrate. | 04-04-2013 |
20130102119 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A fin field-effect-transistor fabricated by forming a dummy fin structure on a semiconductor substrate. A dielectric layer is formed on the semiconductor substrate. The dielectric layer surrounds the dummy fin structure. The dummy fin structure is removed to form a cavity within the dielectric layer. The cavity exposes a portion of the semiconductor substrate thereby forming an exposed portion of the semiconductor substrate within the cavity. A dopant is implanted into the exposed portion of the semiconductor substrate within the cavity thereby creating a dopant implanted exposed portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. | 04-25-2013 |
20130102130 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A fin field-effect-transistor fabricated by forming a dummy fin structure on a semiconductor substrate. A dielectric layer is formed on the semiconductor substrate. The dielectric layer surrounds the dummy fin structure. The dummy fin structure is removed to form a cavity within the dielectric layer. The cavity exposes a portion of the semiconductor substrate thereby forming an exposed portion of the semiconductor substrate within the cavity. A dopant is implanted into the exposed portion of the semiconductor substrate within the cavity thereby creating a dopant implanted exposed portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. | 04-25-2013 |
20130134517 | BORDERLESS CONTACT FOR ULTRA-THIN BODY DEVICES - After formation of a semiconductor device on a semiconductor-on-insulator (SOI) layer, a first dielectric layer is formed over a recessed top surface of a shallow trench isolation structure. A second dielectric layer that can be etched selective to the first dielectric layer is deposited over the first dielectric layer. A contact via hole for a device component located in or on a top semiconductor layer is formed by an etch. During the etch, the second dielectric layer is removed selective to the first dielectric layer, thereby limiting overetch into the first dielectric layer. Due to the etch selectivity, a sufficient amount of the first dielectric layer is present between the bottom of the contact via hole and a bottom semiconductor layer, thus providing electrical isolation for the ETSOI device from the bottom semiconductor layer. | 05-30-2013 |
20130134523 | CMOS TRANSISTORS HAVING DIFFERENTIALLY STRESSED SPACERS - CMOS transistors are formed incorporating a gate electrode having tensely stressed spacers on the gate sidewalls of an n channel field effect transistor and having compressively stressed spacers on the gate sidewalls of a p channel field effect transistor to provide differentially stressed channels in respective transistors to increase carrier mobility in the respective channels. | 05-30-2013 |
20130143371 | DUAL-DEPTH SELF-ALIGNED ISOLATION STRUCTURE FOR A BACK GATE ELECTRODE - Doped semiconductor back gate regions self-aligned to active regions are formed by first patterning a top semiconductor layer and a buried insulator layer to form stacks of a buried insulator portion and a semiconductor portion. Oxygen is implanted into an underlying semiconductor layer at an angle so that oxygen-implanted regions are formed in areas that are not shaded by the stack or masking structures thereupon. The oxygen implanted portions are converted into deep trench isolation structures that are self-aligned to sidewalls of the active regions, which are the semiconductor portions in the stacks. Dopant ions are implanted into the portions of the underlying semiconductor layer between the deep trench isolation structures to form doped semiconductor back gate regions. A shallow trench isolation structure is formed on the deep trench isolation structures and between the stacks. | 06-06-2013 |
20130175579 | TRANSISTOR WITH RECESSED CHANNEL AND RAISED SOURCE/DRAIN - A transistor includes a first semiconductor layer. A second semiconductor layer is located on the first semiconductor layer. A portion of the second semiconductor layer is removed to expose a first portion of the first semiconductor layer and to provide vertical sidewalls of the second semiconductor layer. A gate spacer is located on the second semiconductor layer. A gate dielectric includes a first portion located on the first portion of the first semiconductor layer and a second portion adjacent to the vertical sidewalls of the second semiconductor layer. A gate conductor is located on the first portion of the gate dielectric and abuts the gate dielectric second portion. A channel region is located in at least part of the first portion of the first semiconductor layer. Raised source/drain regions are located in the second semiconductor layer. At least part of the raised source/drain regions is located below the gate spacer. | 07-11-2013 |
20130175618 | FINFET DEVICE - A method for fabricating a field effect transistor device includes removing a portion of a first semiconductor layer and a first insulator layer to expose a portion of a second semiconductor layer, wherein the second semiconductor layer is disposed on a second insulator layer, the first insulator layer is disposed on the second semiconductor layer, and the first semiconductor layer is disposed on the first insulator layer, removing portions of the first semiconductor layer to form a first fin disposed on the first insulator layer and removing portions of the second semiconductor layer to form a second fin disposed on the second insulator layer, and forming a first gate stack over a portion of the first fin and forming a second gate stack over a portion of the second fin. | 07-11-2013 |
20130175619 | SILICON-ON-INSULATOR TRANSISTOR WITH SELF-ALIGNED BORDERLESS SOURCE/DRAIN CONTACTS - A transistor includes a semiconductor layer, a gate spacer on the semiconductor layer, a gate dielectric comprising a first portion above the semiconductor layer and a second portion on sidewalls of the gate spacer, a work function metal layer comprising a first portion on the first portion of the gate dielectric and a second portion on sidewalls of the gate dielectric, a gate conductor on the first portion of the work function layer and abutting the second portion of the work function layer, a dielectric layer on the semiconductor layer and abutting the gate spacer, an oxide film above only one of the work function layer and the gate conductor, an oxide cap, source/drain regions, and a source/drain contact passing through the dielectric layer and contacting an upper surface of one of the source/drain regions. A portion of the source/drain contact is located directly on the oxide cap. | 07-11-2013 |
20130175622 | ELECTRICAL ISOLATION STRUCTURES FOR ULTRA-THIN SEMICONDUCTOR-ON-INSULATOR DEVICES - After formation of raised source and drain regions, a conformal dielectric material liner is deposited within recessed regions formed by removal of shallow trench isolation structures and underlying portions of a buried insulator layer in a semiconductor-on-insulator (SOI) substrate. A dielectric material that is different from the material of the conformal dielectric material liner is subsequently deposited and planarized to form a planarized dielectric material layer. The planarized dielectric material layer is recessed selective to the conformal dielectric material liner to form dielectric fill portions that fill the recessed regions. Horizontal portions of the conformal dielectric material liner are removed by an anisotropic etch, while remaining portions of the conformal dielectric material liner form an outer gate spacer. At least one contact-level dielectric layer is deposited. Contact via structures electrically isolated from a handle substrate can be formed within the contact via holes. | 07-11-2013 |
20130175625 | LOW SERIES RESISTANCE TRANSISTOR STRUCTURE ON SILICON ON INSULATOR LAYER - A transistor structure includes a channel located in an extremely thin silicon on insulator (ETSOI) layer and disposed between a raised source and a raised drain, a gate structure having a gate conductor disposed over the channel and between the source and the drain, and a gate spacer layer disposed over the gate conductor. The raised source and the raised drain each have a facet that is upwardly sloping away from the gate structure. A lower portion of the source and a lower portion of the drain are separated from the channel by an extension region containing a dopant species diffused from a dopant-containing glass. | 07-11-2013 |
20130178022 | METHOD FOR FABRICATING TRANSISTOR WITH RECESSED CHANNEL AND RAISED SOURCE/DRAIN - A method is provided for fabricating a transistor. According to the method, a second semiconductor layer is formed on a first semiconductor layer, and a dummy gate structure is formed on the second semiconductor layer. A gate spacer is formed on sidewalls of the dummy gate structure, and the dummy gate structure is removed to form a cavity. The second semiconductor layer beneath the cavity is removed. A gate dielectric is formed on the first portion of the first semiconductor layer and adjacent to the sidewalls of the second semiconductor layer and sidewalls of the gate spacer. A gate conductor is formed on the first portion of the gate dielectric and abutting the second portion of the gate dielectric. Raised source/drain regions are formed in the second semiconductor layer, with at least part of the raised source/drain regions being below the gate spacer. | 07-11-2013 |
20130178052 | METHOD FOR FABRICATING SILICON-ON-INSULATOR TRANSISTOR WITH SELF-ALIGNED BORDERLESS SOURCE/DRAIN CONTACTS - A method is provided for fabricating a transistor. A replacement gate stack is formed on a semiconductor layer, a gate spacer is formed, and a dielectric layer is formed. The dummy gate stack is removed to form a cavity. A gate dielectric and a work function metal layer are formed in the cavity. The cavity is filled with a gate conductor. One and only one of the gate conductor and the work function metal layer are selectively recessed. An oxide film is formed in the recess such that its upper surface is co-planar with the upper surface of the dielectric layer. The oxide film is used to selectively grow an oxide cap. An interlayer dielectric is formed and etched to form a cavity for a source/drain contact. A source/drain contact is formed in the contact cavity, with a portion of the source/drain contact being located directly on the oxide cap. | 07-11-2013 |
20130187129 | SEMICONDUCTOR DEVICES FABRICATED BY DOPED MATERIAL LAYER AS DOPANT SOURCE - A method of forming a semiconductor device is provided, in which the dopant for the source and drain regions is introduced from a doped dielectric layer. In one example, a gate structure is formed on a semiconductor layer of an SOI substrate, in which the thickness of the semiconductor layer is less than 10 nm. A doped dielectric layer is formed over at least the portion of the semiconductor layer that is adjacent to the gate structure. The dopant from the doped dielectric layer is driven into the portion of the semiconductor layer that is adjacent to the gate structure. The dopant diffused into the semiconductor provides source and drain extension regions. | 07-25-2013 |
20130210206 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A fin field-effect-transistor fabricated by forming a dummy fin structure on a semiconductor substrate. A dielectric layer is formed on the semiconductor substrate. The dielectric layer surrounds the dummy fin structure. The dummy fin structure is removed to form a cavity within the dielectric layer. The cavity exposes a portion of the semiconductor substrate thereby forming an exposed portion of the semiconductor substrate within the cavity. A dopant is implanted into the exposed portion of the semiconductor substrate within the cavity thereby creating a dopant implanted exposed portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. | 08-15-2013 |
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 |
20130292766 | SEMICONDUCTOR SUBSTRATE WITH TRANSISTORS HAVING DIFFERENT THRESHOLD VOLTAGES - A semiconductor integrated circuit is provided and includes a first field effect transistor (FET) device and a second FET device formed on a semiconductor substrate. The first FET device has raised source/drain (RSD) structures grown at a first height. The second FET device has RSD structures grown at a second height greater than the first height such that a threshold voltage of the second FET device is greater than a threshold voltage of the first FET device. | 11-07-2013 |
20130295730 | SEMICONDUCTOR SUBSTRATE WITH TRANSISTORS HAVING DIFFERENT THRESHOLD VOLTAGES - A method of creating a semiconductor integrated circuit is disclosed. The method includes forming a first field effect transistor (FET) device and a second FET device on a semiconductor substrate. The method includes epitaxially growing raised source/drain (RSD) structures for the first FET device at a first height. The method includes epitaxially growing raised source/drain (RSD) structures for the second FET device at a second height. The second height is greater than the first height such that a threshold voltage of the second FET device is greater than a threshold voltage of the first FET device. | 11-07-2013 |
20130307043 | MOS CAPACITORS WITH A FINFET PROCESS - Capacitors include a first electrical terminal that has fins formed from doped semiconductor on a top layer of doped semiconductor on a semiconductor-on-insulator substrate; a second electrical terminal that has an undoped material having bottom surface shape that is complementary to the first electrical terminal, such that an interface area between the first electrical terminal and the second electrical terminal is larger than a capacitor footprint; and a dielectric layer separating the first and second electrical terminals. | 11-21-2013 |
20130309832 | MOS CAPACITORS WITH A FINFET PROCESS - Methods for capacitor fabrication include doping a capacitor region of a semiconductor layer in a semiconductor-on-insulator substrate; partially etching the semiconductor layer to produce a first terminal layer comprising doped semiconductor fins on a remaining base of doped semiconductor; forming a dielectric layer over the first terminal layer; and forming a second terminal layer over the dielectric layer in a finFET process. | 11-21-2013 |
20130319613 | CUT-VERY-LAST DUAL-EPI FLOW - A method for making dual-epi FinFETs is described. The method includes adding a first epitaxial material to an array of fins. The method also includes covering at least a first portion of the array of fins using a first masking material and removing the first epitaxial material from an uncovered portion of the array of fins. Adding a second epitaxial material to the fins in the uncovered portion of the array of fins is included in the method. The method also includes covering a second portion of the array of fins using a second masking material and performing a directional etch using the first masking material and the second masking material. Apparatus and computer program products are also described. | 12-05-2013 |
20130320411 | BORDERLESS CONTACTS FOR METAL GATES THROUGH SELECTIVE CAP DEPOSITION - A semiconductor device including a gate structure present on a channel portion of a substrate, in which the gate structure includes at least one high-k gate dielectric layer and at least one metal gate conductor. A source region and a drain region is present on opposing sides of the channel portion of the substrate. A metal oxide gate cap is present on an upper surface of the metal gate conductor. The metal oxide composition of the metal oxide gate cap may be zirconium oxide, aluminum oxide, magnesium oxide, hafnium oxide or a combination thereof. Contacts may extend through an intralevel dielectric layer into contact with at least one of the source region and the drain region. | 12-05-2013 |
20130320414 | BORDERLESS CONTACTS FOR METAL GATES THROUGH SELECTIVE CAP DEPOSITION - A semiconductor device including a gate structure present on a channel portion of a substrate, in which the gate structure includes at least one high-k gate dielectric layer and at least one metal gate conductor. A source region and a drain region is present on opposing sides of the channel portion of the substrate. A metal oxide gate cap is present on an upper surface of the metal gate conductor. The metal oxide composition of the metal oxide gate cap may be zirconium oxide, aluminum oxide, magnesium oxide, hafnium oxide or a combination thereof. Contacts may extend through an intralevel dielectric layer into contact with at least one of the source region and the drain region. | 12-05-2013 |
20130341754 | SHALLOW TRENCH ISOLATION STRUCTURES - Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate. | 12-26-2013 |
20130344677 | SHALLOW TRENCH ISOLATION STRUCTURES - Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate. | 12-26-2013 |
20140001555 | UNDERCUT INSULATING REGIONS FOR SILICON-ON-INSULATOR DEVICE | 01-02-2014 |
20140017859 | METHOD FOR FABRICATING TRANSISTOR WITH RECESSED CHANNEL AND RAISED SOURCE/DRAIN - A method is provided for fabricating a transistor. According to the method, a second semiconductor layer is formed on a first semiconductor layer, and a dummy gate structure is formed on the second semiconductor layer. A gate spacer is formed on sidewalls of the dummy gate structure, and the dummy gate structure is removed to form a cavity. The second semiconductor layer beneath the cavity is removed. A gate dielectric is formed on the first portion of the first semiconductor layer and adjacent to the sidewalls of the second semiconductor layer and sidewalls of the gate spacer. A gate conductor is formed on the first portion of the gate dielectric and abutting the second portion of the gate dielectric. Raised source/drain regions are formed in the second semiconductor layer, with at least part of the raised source/drain regions being below the gate spacer. | 01-16-2014 |
20140024198 | POST-GATE ISOLATION AREA FORMATION FOR FIN FIELD EFFECT TRANSISTOR DEVICE - A method for fin field effect transistor (finFET) device formation includes forming a plurality of fins on a substrate; forming a gate region over the plurality of fins; and forming isolation areas for the finFET device after formation of the gate region, wherein forming the isolation areas for the finFET device comprises performing one of oxidation or removal of a subset of the plurality of fins. | 01-23-2014 |
20140045312 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A process fabricates a fin field-effect-transistor by forming a dummy fin structure on a semiconductor substrate. A dielectric layer is formed on the semiconductor substrate. The dielectric layer surrounds the dummy fin structure. The dummy fin structure is removed to form a cavity within the dielectric layer. The cavity exposes a portion of the semiconductor substrate thereby forming an exposed portion of the semiconductor substrate within the cavity. A dopant is implanted into the exposed portion of the semiconductor substrate within the cavity thereby creating a dopant implanted exposed portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. | 02-13-2014 |
20140048857 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A process fabricates a fin field-effect-transistor by implanting a dopant into an exposed portion of a semiconductor substrate within a cavity. The cavity is formed in a dielectric layer on the semiconductor substrate. The cavity exposes the portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. A height of the cavity defines a height of the epitaxially grown semiconductor. | 02-20-2014 |
20140051216 | Replacement Gate ETSOI With Sharp Junction - A method includes providing a silicon-on-insulator wafer (e.g., an ETSOI wafer); forming a sacrificial gate structure that overlies a sacrificial insulator layer; forming raised source/drains adjacent to the sacrificial gate structure; depositing an oxide layer that covers the raised source/drains and that surrounds the sacrificial gate structure; and removing the sacrificial gate structure leaving an opening that extends to the sacrificial insulator layer. The method further includes widening the opening so as to expose some of the raised source/drains, removing the sacrificial insulator layer and forming a spacer layer on sidewalls of the opening, the spacer layer covering only an upper portion of the exposed raised source/drains, and depositing a layer of gate dielectric material within the opening. A gate conductor is deposited within the opening. | 02-20-2014 |
20140054717 | INTEGRATION OF MULTIPLE THRESHOLD VOLTAGE DEVICES FOR COMPLEMENTARY METAL OXIDE SEMICONDUCTOR USING FULL METAL GATE - A substrate is provided, having formed thereon a first region and a second region of a complementary type to the first region. A gate dielectric is deposited over the substrate, and a first full metal gate stack is deposited over the gate dielectric. The first full metal gate stack is removed over the first region to produce a resulting structure. Over the resulting structure, a second full metal gate stack is deposited, in contact with the gate dielectric over the first region. The first and second full metal gate stacks are encapsulated. | 02-27-2014 |
20140061582 | SUSPENDED NANOWIRE STRUCTURE - A mandrel having vertical planar surfaces is formed on a single crystalline semiconductor layer. An epitaxial semiconductor layer is formed on the single crystalline semiconductor layer by selective epitaxy. A first spacer is formed around an upper portion of the mandrel. The epitaxial semiconductor layer is vertically recessed employing the first spacers as an etch mask. A second spacer is formed on sidewalls of the first spacer and vertical portions of the epitaxial semiconductor layer. Horizontal bottom portions of the epitaxial semiconductor layer are etched from underneath the vertical portions of the epitaxial semiconductor layer to form a suspended ring-shaped semiconductor fin that is attached to the mandrel. A center portion of the mandrel is etched employing a patterned mask layer that covers two end portions of the mandrel. A suspended semiconductor fin is provided, which is suspended by a pair of support structures. | 03-06-2014 |
20140061794 | FINFET WITH SELF-ALIGNED PUNCHTHROUGH STOPPER - A finFET with self-aligned punchthrough stopper and methods of manufacture are disclosed. The method includes forming spacers on sidewalls of a gate structure and fin structures of a finFET device. The method further includes forming a punchthrough stopper on exposed sidewalls of the fin structures, below the spacers. The method further includes diffusing dopants from the punchthrough stopper into the fin structures. The method further includes forming source and drain regions adjacent to the gate structure and fin structures. | 03-06-2014 |
20140061799 | SILICON-ON-INSULATOR TRANSISTOR WITH SELF-ALIGNED BORDERLESS SOURCE/DRAIN CONTACTS - A method is provided for fabricating an integrated circuit that includes multiple transistors. A replacement gate stack is formed on a semiconductor layer, a gate spacer is formed, and a dielectric layer is formed. The dummy gate stack is removed to form a cavity. A gate dielectric and a work function metal layer are formed in the cavity. The cavity is filled with a gate conductor. One and only one of the gate conductor and the work function metal layer are selectively recessed. An oxide film is formed in the recess such that its upper surface is co-planar with the upper surface of the dielectric layer. The oxide film is used to selectively grow an oxide cap. An interlayer dielectric is formed and etched to form a cavity for a source/drain contact. A source/drain contact is formed in the contact cavity, with a portion of the source/drain contact being located directly on the oxide cap. | 03-06-2014 |
20140061800 | ELECTRICAL ISOLATION STRUCTURES FOR ULTRA-THIN SEMICONDUCTOR-ON-INSULATOR DEVICES - After formation of raised source and drain regions, a conformal dielectric material liner is deposited within recessed regions formed by removal of shallow trench isolation structures and underlying portions of a buried insulator layer in a semiconductor-on-insulator (SOI) substrate. A dielectric material that is different from the material of the conformal dielectric material liner is subsequently deposited and planarized to form a planarized dielectric material layer. The planarized dielectric material layer is recessed selective to the conformal dielectric material liner to form dielectric fill portions that fill the recessed regions. Horizontal portions of the conformal dielectric material liner are removed by an anisotropic etch, while remaining portions of the conformal dielectric material liner form an outer gate spacer. At least one contact-level dielectric layer is deposited. Contact via structures electrically isolated from a handle substrate can be formed within the contact via holes. | 03-06-2014 |
20140077296 | METHOD AND STRUCTURE FOR FINFET WITH FINELY CONTROLLED DEVICE WIDTH - A structure and method for fabricating finFETs of varying effective device widths is disclosed. Groups of fins are shortened by a predetermined amount to achieve an effective device width that is equivalent to a real (non-integer) number of full-sized fins. The bottom of each group of fins is coplanar, while the tops of the fins from the different groups of fins may be at different levels. | 03-20-2014 |
20140084382 | DUAL METAL FILL AND DUAL THRESHOLD VOLTAGE FOR REPLACEMENT GATE METAL DEVICES - A structure and method for forming a dual metal fill and dual threshold voltage for replacement gate metal devices is disclosed. A selective deposition process involving titanium and aluminum is used to allow formation of two adjacent transistors with different fill metals and different workfunction metals, enabling different threshold voltages in the adjacent transistors. | 03-27-2014 |
20140103450 | HYBRID ORIENTATION FIN FIELD EFFECT TRANSISTOR AND PLANAR FIELD EFFECT TRANSISTOR - A substrate including a handle substrate, a lower insulator layer, a buried semiconductor layer, an upper insulator layer, and a top semiconductor layer is provided. Semiconductor fins can be formed by patterning a portion of the buried semiconductor layer after removal of the upper insulator layer and the top semiconductor layer in a fin region, while a planar device region is protected by an etch mask. A disposable fill material portion is formed in the fin region, and a shallow trench isolation structure can be formed in the planar device region. The disposable fill material portion is removed, and gate stacks for a planar field effect transistor and a fin field effect transistor can be simultaneously formed. Alternately, disposable gate structures and a planarization dielectric layer can be formed, and replacement gate stacks can be subsequently formed. | 04-17-2014 |
20140117421 | SELF-ALIGNED CONTACT STRUCTURE FOR REPLACEMENT METAL GATE - A metallic top surface of a replacement gate structure is oxidized to convert a top portion of the replacement gate structure into a dielectric oxide. After removal of a planarization dielectric layer, selective epitaxy is performed to form a raised source region and a raised drain region that extends higher than the topmost surface of the replacement gate structure. A gate level dielectric layer including a first dielectric material is deposited and subsequently planarized employing the raised source and drain regions as stopping structures. A contact level dielectric layer including a second dielectric material is formed over the gate level dielectric layer, and contact via holes are formed employing an etch chemistry that etches the second dielectric material selective to the first dielectric material. Raised source and drain regions are recessed. Self-aligned contact structures can be formed by filling the contact via holes with a conductive material. | 05-01-2014 |
20140145247 | FIN ISOLATION IN MULTI-GATE FIELD EFFECT TRANSISTORS - A method for fabricating a field effect transistor (FET) device includes forming a plurality of semiconductor fins on a substrate, removing a semiconductor fin of the plurality of semiconductor fins from a portion of the substrate, forming an isolation fin that includes a dielectric material on the substrate on the portion of the substrate, and forming a gate stack over the plurality of semiconductor fins and the isolation fin. | 05-29-2014 |
20140145248 | DUMMY FIN FORMATION BY GAS CLUSTER ION BEAM - FinFET structures with dielectric fins and methods of fabrication are disclosed. A gas cluster ion beam (GCIB) tool is used to apply an ion beam to exposed fins, which converts the fins from a semiconductor material such as silicon, to a dielectric such as silicon nitride or silicon oxide. Unlike some prior art techniques, where some fins are removed prior to fin merging, in embodiments of the present invention, fins are not removed. Instead, semiconductor (silicon) fins are converted to dielectric (nitride/oxide) fins where it is desirable to have isolation between groups of fins that comprise various finFET devices on an integrated circuit (IC). | 05-29-2014 |
20140151801 | UNIFORM FINFET GATE HEIGHT - A method including providing a plurality of fins etched from a semiconductor substrate and covered by an oxide layer and a nitride layer, the oxide layer being located between the plurality of fins and the nitride layer, removing a portion of the plurality of fins to form an opening, and forming a dielectric spacer on a sidewall of the opening. The method may also include filling the opening with a fill material, wherein a top surface of the fill material is substantially flush with a top surface of the nitride layer, removing the nitride layer to form a gap between the plurality of fins and the fill material, wherein the fill material has re-entrant geometry extending over the gap, and removing the re-entrant geometry and causing the gap between the plurality of fins and the fill material to widen. | 06-05-2014 |
20140154865 | SHALLOW TRENCH ISOLATION STRUCTURES - Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate. | 06-05-2014 |
20140159123 | ETCH RESISTANT RAISED ISOLATION FOR SEMICONDUCTOR DEVICES - A method including providing fins etched from a semiconductor substrate, the fins covered by an oxide layer and a nitride layer, the oxide layer located between the fins and the nitride layer, removing a portion of the fins to form an opening, and forming a spacer on a sidewall of the opening. The method further including filling the opening above the semiconductor substrate with a first fill material, where a top surface of the fill material is substantially flush with a top surface of the nitride layer, removing the spacer to expose a vertical sidewall of the first fill material, and depositing an encapsulation layer conformally on top of the first fill material, where the encapsulation layer is resistant to wet etching techniques and protects from the unwanted removal of the first fill material during subsequent process techniques. | 06-12-2014 |
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 |
20140175549 | FINFET DEVICE - A method for fabricating a field effect transistor device includes removing a portion of a first semiconductor layer and a first insulator layer to expose a portion of a second semiconductor layer, wherein the second semiconductor layer is disposed on a second insulator layer, the first insulator layer is disposed on the second semiconductor layer, and the first semiconductor layer is disposed on the first insulator layer, removing portions of the first semiconductor layer to form a first fin disposed on the first insulator layer and removing portions of the second semiconductor layer to form a second fin disposed on the second insulator layer, and forming a first gate stack over a portion of the first fin and forming a second gate stack over a portion of the second fin. | 06-26-2014 |
20140187007 | MOSFET INCLUDING ASYMMETRIC SOURCE AND DRAIN REGIONS - At least one drain-side surfaces of a field effect transistor (FET) structure, which can be a structure for a planar FET or a fin FET, is structurally damaged by an angled ion implantation of inert or electrically active dopants, while at least one source-side surface of the transistor is protected from implantation by a gate stack and a gate spacer. Epitaxial growth of a semiconductor material is retarded on the at least one structurally damaged drain-side surface, while epitaxial growth proceeds without retardation on the at least one source-side surface. A raised epitaxial source region has a greater thickness than a raised epitaxial drain region, thereby providing an asymmetric FET having lesser source-side external resistance than drain-side external resistance, and having lesser drain-side overlap capacitance than source-side overlap capacitance. | 07-03-2014 |
20140191321 | FINFET WITH DIELECTRIC ISOLATION BY SILICON-ON-NOTHING AND METHOD OF FABRICATION - An improved finFET and method of fabrication using a silicon-on-nothing process flow is disclosed. Nitride spacers protect the fin sides during formation of cavities underneath the fins for the silicon-on-nothing (SON) process. A flowable oxide fills the cavities to form an insulating dielectric layer under the fins. | 07-10-2014 |
20140264496 | STRESS ENHANCED FINFET DEVICES - A non-planar semiconductor with enhanced strain includes a substrate and at least one semiconducting fin formed on a surface of the substrate. A gate stack is formed on a portion of the at least one semiconducting fin. A stress liner is formed over at least each of a plurality of sidewalls of the at least one semiconducting fin and the gate stack. The stress liner imparts stress to at least a source region, a drain region, and a channel region of the at least one semiconducting fin. The channel region is located in at least one semiconducting fin beneath the gate stack. | 09-18-2014 |
20140264598 | STRESS ENHANCED FINFET DEVICES - A non-planar semiconductor with enhanced strain includes a substrate and at least one semiconducting fin formed on a surface of the substrate. A gate stack is formed on a portion of the at least one semiconducting fin. A stress liner is formed over at least each of a plurality of sidewalls of the at least one semiconducting fin and the gate stack. The stress liner imparts stress to at least a source region, a drain region, and a channel region of the at least one semiconducting fin. The channel region is located in at least one semiconducting fin beneath the gate stack. | 09-18-2014 |
20140295647 | BULK FIN-FIELD EFFECT TRANSISTORS WITH WELL DEFINED ISOLATION - A computer program storage product includes instructions for forming a fin field-effect-transistor. The instructions are configured to perform a method. The method includes implanting a dopant into an exposed portion of a semiconductor substrate within a cavity. The cavity is formed in a dielectric layer on the semiconductor substrate. The cavity exposes the portion of the semiconductor substrate within the cavity. A semiconductor layer is epitaxially grown within the cavity atop the dopant implanted exposed portion of the semiconductor substrate. A height of the cavity defines a height of the epitaxially grown semiconductor. | 10-02-2014 |
20140319611 | UNIFORM FINFET GATE HEIGHT - A structure including a first plurality of fins and a second plurality of fins etched from a semiconductor substrate, and a fill material located above the semiconductor substrate and between the first plurality of fins and the second plurality of fins, the fill material does not contact either the first plurality of fins or the second plurality of fins. | 10-30-2014 |
20140377927 | SELF-ALIGNED CONTACT STRUCTURE FOR REPLACEMENT METAL GATE - A metallic top surface of a replacement gate structure is oxidized to convert a top portion of the replacement gate structure into a dielectric oxide. After removal of a planarization dielectric layer, selective epitaxy is performed to form a raised source region and a raised drain region that extends higher than the topmost surface of the replacement gate structure. A gate level dielectric layer including a first dielectric material is deposited and subsequently planarized employing the raised source and drain regions as stopping structures. A contact level dielectric layer including a second dielectric material is formed over the gate level dielectric layer, and contact via holes are formed employing an etch chemistry that etches the second dielectric material selective to the first dielectric material. Raised source and drain regions are recessed. Self-aligned contact structures can be formed by filling the contact via holes with a conductive material. | 12-25-2014 |
20150053913 | SUSPENDED NANOWIRE STRUCTURE - A mandrel having vertical planar surfaces is formed on a single crystalline semiconductor layer. An epitaxial semiconductor layer is formed on the single crystalline semiconductor layer by selective epitaxy. A first spacer is formed around an upper portion of the mandrel. The epitaxial semiconductor layer is vertically recessed employing the first spacers as an etch mask. A second spacer is formed on sidewalls of the first spacer and vertical portions of the epitaxial semiconductor layer. Horizontal bottom portions of the epitaxial semiconductor layer are etched from underneath the vertical portions of the epitaxial semiconductor layer to form a suspended ring-shaped semiconductor fin that is attached to the mandrel. A center portion of the mandrel is etched employing a patterned mask layer that covers two end portions of the mandrel. A suspended semiconductor fin is provided, which is suspended by a pair of support structures. | 02-26-2015 |
20150054033 | FINFET WITH SELF-ALIGNED PUNCHTHROUGH STOPPER - A finFET with self-aligned punchthrough stopper and methods of manufacture are disclosed. The method includes forming spacers on sidewalls of a gate structure and fin structures of a finFET device. The method further includes forming a punchthrough stopper on exposed sidewalls of the fin structures, below the spacers. The method further includes diffusing dopants from the punchthrough stopper into the fin structures. The method further includes forming source and drain regions adjacent to the gate structure and fin structures. | 02-26-2015 |
20150064855 | FINFET WITH DIELECTRIC ISOLATION BY SILICON-ON-NOTHING AND METHOD OF FABRICATION - An improved finFET and method of fabrication using a silicon-on-nothing process flow is disclosed. Nitride spacers protect the fin sides during formation of cavities underneath the fins for the silicon-on-nothing (SON) process. A flowable oxide fills the cavities to form an insulating dielectric layer under the fins. | 03-05-2015 |
20150064874 | DUMMY FIN FORMATION BY GAS CLUSTER ION BEAM - FinFET structures with dielectric fins and methods of fabrication are disclosed. A gas cluster ion beam (GCIB) tool is used to apply an ion beam to exposed fins, which converts the fins from a semiconductor material such as silicon, to a dielectric such as silicon nitride or silicon oxide. Unlike some prior art techniques, where some fins are removed prior to fin merging, in embodiments of the present invention, fins are not removed. Instead, semiconductor (silicon) fins are converted to dielectric (nitride/oxide) fins where it is desirable to have isolation between groups of fins that comprise various finFET devices on an integrated circuit (IC). | 03-05-2015 |