Patent application number | Description | Published |
20080224182 | TRENCH-EDGE-DEFECT-FREE RECRYSTALLIZATION BY EDGE-ANGLE-OPTIMIZED SOLID PHASE EPITAXY: METHOD AND APPLICATIONS TO HYBRID ORIENTATION SUBSTRATES - The present invention discloses the use of edge-angle-optimized solid phase epitaxy for forming hybrid orientation substrates comprising changed-orientation Si device regions free of the trench-edge defects typically seen when trench-isolated regions of Si are recrystallized to the orientation of an underlying single-crystal Si template after an amorphization step. For the case of amorphized Si regions recrystallizing to (100) surface orientation, the trench-edge-defect-free recrystallization of edge-angle-optimized solid phase epitaxy may be achieved in rectilinear Si device regions whose edges align with the (100) crystal's in-plane <100> directions. | 09-18-2008 |
20080248626 | SHALLOW TRENCH ISOLATION SELF-ALIGNED TO TEMPLATED RECRYSTALLIZATION BOUNDARY - A hybrid orientation direct-semiconductor-bond (DSB) substrate with shallow trench isolation (STI) that is self-aligned to recrystallization boundaries is formed by patterning a hard mask layer for STI, a first amorphization implantation into openings in the hard mask layer, lithographic patterning of portions of a top semiconductor layer, a second amorphization implantation into exposed portions of the DSB substrate, recrystallization of the portions of the top semiconductor layer, and formation of STI utilizing the pattern in the hard mask layer. The edges of patterned photoresist for the second amorphization implantation are located within the openings in the patterned hard mask layer. Defective boundary regions formed underneath the openings in the hard mask layer are removed during the formation of STI to provide a leakage path free substrate. Due to elimination of a requirement for increased STI width, device density is increased compared to non-self-aligning process integration schemes. | 10-09-2008 |
20080251880 | MIXED ORIENTATION AND MIXED MATERIAL SEMICONDUCTOR-ON-INSULATOR WAFER - The present disclosure relates, generally, to a semiconductor substrate with a planarized surface comprising mixed single-crystal orientation regions and/or mixed single-crystal semiconductor material regions, where each region is electrically isolated. In accordance with one embodiment of the disclosure CMOS devices on SOI regions are manufactured on semiconductors having different orientations. According to another embodiment, an SOI device is contemplated as having a plurality of semiconductor regions having at least one of a different semiconductor material, crystalline lattice constant or lattice strain. Methods and processes for fabricating the different embodiments of the invention is also disclosed. | 10-16-2008 |
20080258220 | ION IMPLANTATION COMBINED WITH IN SITU OR EX SITU HEAT TREATMENT FOR IMPROVED FIELD EFFECT TRANSISTORS - This invention teaches methods of combining ion implantation steps with in situ or ex situ heat treatments to avoid and/or minimize implant-induced amorphization (a potential problem for source/drain (S/D) regions in FETs in ultrathin silicon on insulator layers) and implant-induced plastic relaxation of strained S/D regions (a potential problem for strained channel FETs in which the channel strain is provided by embedded S/D regions lattice mismatched with an underlying substrate layer). In a first embodiment, ion implantation is combined with in situ heat treatment by performing the ion implantation at elevated temperature. In a second embodiment, ion implantation is combined with ex situ heat treatments in a “divided-dose-anneal-in-between” (DDAB) scheme that avoids the need for tooling capable of performing hot implants. | 10-23-2008 |
20080286917 | LASER PROCESSING METHOD FOR TRENCH-EDGE-DEFECT-FREE SOLID PHASE EPITAXY IN CONFINED GEOMETRICS - The present invention provides an improved amorphization/templated recrystallization (ATR) method for fabricating low-defect-density hybrid orientation substrates. ATR methods for hybrid orientation substrate fabrication generally start with a Si layer having a first orientation bonded to a second Si layer or substrate having a second orientation. Selected regions of the first Si layer are amorphized and then recrystallized into the orientation of the second Si layer by using the second Si layer as a template. In particular, this invention provides a melt-recrystallization ATR method, for use alone or in combination with non-melt-recrystallization ATR methods, in which selected Si regions bounded by dielectric-filled trenches are induced to undergo an orientation change by the steps of preamorphization, laser-induced melting, and corner-defect-free templated recrystallization from the melt. | 11-20-2008 |
20080303068 | FIELD EFFECT TRANSISTOR USING CARBON BASED STRESS LINER - A stress liner for use within a semiconductor structure that includes a field effect device has a dielectric constant less than about 7 and a compressive stress greater than about 5 GPa. The stress liner may be formed of a carbon based material, preferably a tetrahedral amorphous carbon (ta-C) material including at least about 60 atomic percent carbon and no greater than C about 40 atomic percent hydrogen. The carbon based material may be either a dielectric material, or given appropriate additional dielectric isolation structures, a semiconductor material. In particular, a ta-C stress liner may be formed using a filtered cathodic vacuum arc (FCVA) physical vapor deposition (PVD) method. | 12-11-2008 |
20090065867 | ORIENTATION-OPTIMIZED PFETS IN CMOS DEVICES EMPLOYING DUAL STRESS LINERS - A PFET is provided on a silicon layer having a (110) surface orientation and located in a substrate. A compressive stress liner disposed on the gate and source/drain regions of the PFET generates a primary longitudinal compressive strain along the direction of the PFET channel. A tensile stress liner disposed on at least one NFET located transversely adjacent to the PFET generates a primary longitudinal tensile strain along the direction of the NFET channel. A secondary stress field from the at least one NFET tensile liner generates a beneficial transverse tensile stress in the PFET channel. The net benefits of the primary compressive longitudinal strain and the secondary tensile transverse stress are maximized when the azimuthal angle between the direction of the PFET channel and an in-plane [1 | 03-12-2009 |
20090108301 | HYBRID ORIENTATION SEMICONDUCTOR STRUCTURE WITH REDUCED BOUNDARY DEFECTS AND METHOD OF FORMING SAME - The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template. This optimal arrangement of DSB layer, base substrate, and amorphized region orientation provides a near-vertical, essentially defect-free boundary between original-orientation and changed-orientation silicon regions, thus enabling complete boundary region removal with smaller footprint shallow trench isolation than possible with ATR methods not so optimized. | 04-30-2009 |
20090173967 | STRAINED-CHANNEL FET COMPRISING TWIST-BONDED SEMICONDUCTOR LAYER - This invention provides a strained-channel field effect transistor (FET) in which the semiconductor of the channel of the FET is formed in a compliant substrate layer disposed over a twist-bonded semiconductor interface. This FET geometry increases the efficacy of local stress elements such as stress liners and embedded lattice-mismatched source/drain regions by mechanically decoupling the semiconductor of the channel region from the underlying rigid substrate. These strained-channel FETs may be incorporated into complementary metal oxide semiconductor (CMOS) circuits in various combinations. In one embodiment of this invention, both pFETs and nFETs are in a twist-bonded (001) silicon layer on a (001) silicon base layer. In another embodiment, pFETs are in a twist-bonded (011) silicon layer on a (001) silicon base layer and nFETs are in a conventional, non-twist-bonded (001) silicon base layer. This invention also provides a twist-bonded semiconductor layer on a polycrystalline base layer, as well as methods for fabricating the aforementioned FETs. | 07-09-2009 |
20090242942 | ASYMMETRIC SOURCE AND DRAIN FIELD EFFECT STRUCTURE AND METHOD - A semiconductor structure, such as a CMOS semiconductor structure, includes a field effect device that includes a plurality of source and drain regions that are asymmetric. Such a source region and drain region asymmetry is induced by fabricating the semiconductor structure using a semiconductor substrate that includes a horizontal plateau region contiguous with and adjoining a sloped incline region. Within the context of a CMOS semiconductor structure, such a semiconductor substrate allows for fabrication of a pFET and an nFET upon different crystallographic orientation semiconductor regions, while one of the pFET and the nFET (i.e., typically the pFET) has asymmetric source and drain regions. | 10-01-2009 |
20090298258 | QUASI-HYDROPHOBIC Si-Si WAFER BONDING USING HYDROPHILIC Si SURFACES AND DISSOLUTION OF INTERFACIAL BONDING OXIDE - The present invention provides a method for removing or reducing the thickness of ultrathin interfacial oxides remaining at Si—Si interfaces after silicon wafer bonding. In particular, the invention provides a method for removing ultrathin interfacial oxides remaining after hydrophilic Si—Si wafer bonding to create bonded Si—Si interfaces having properties comparable to those achieved with hydrophobic bonding. Interfacial oxide layers of order of about 2 to about 3 nm are dissolved away by high temperature annealing, for example, an anneal at 1300°-1330° C. for 1-5 hours. The inventive method is used to best advantage when the Si surfaces at the bonded interface have different surface orientations, for example, when a Si surface having a (100) orientation is bonded to a Si surface having a (110) orientation. In a more general aspect of the invention, the similar annealing processes may be used to remove undesired material disposed at a bonded interface of two silicon-containing semiconductor materials. The two silicon-containing semiconductor materials may be the same or different in surface crystal orientation, microstructure (single-crystal, polycrystalline, or amorphous), and composition. | 12-03-2009 |
20090302353 | STRUCTURES CONTAINING ELECTRODEPOSITED GERMANIUM AND METHODS FOR THEIR FABRICATION - Methods for electrodepositing germanium on various semiconductor substrates such as Si, Ge, SiGe, and GaAs are provided. The electrodeposited germanium can be formed as a blanket or patterned film, and may be crystallized by solid phase epitaxy to the orientation of the underlying semiconductor substrate by subsequent annealing. These plated germanium layers may be used as the channel regions of high-mobility channel field effect transistors (FETs) in complementary metal oxide semiconductor (CMOS) circuits. | 12-10-2009 |
20100006850 | BEOL COMPATIBLE FET STRUCTURE - This invention provides structures and a fabrication process for incorporating thin film transistors in back end of the line (BEOL) interconnect structures. The structures and fabrication processes described are compatible with processing requirements for the BEOL interconnect structures. The structures and fabrication processes utilize existing processing steps and materials already incorporated in interconnect wiring levels in order to reduce added cost associated with incorporating thin film transistors in the these levels. The structures enable vertical (3D) integration of multiple levels with improved manufacturability and reliability as compared to prior art methods of 3D integration. | 01-14-2010 |
20100015790 | TiC AS A THERMALLY STABLE p-METAL CARBIDE ON HIGH k SiO2 GATE STACKS - A compound metal comprising TiC which is a p-type metal having a workfunction of about 4.75 to about 5.3, preferably about 5, eV that is thermally stable on a gate stack comprising a high k dielectric and an interfacial layer is provided as well as a method of fabricating the TiC compound metal. Furthermore, the TiC metal compound of the present invention is a very efficient oxygen diffusion barrier at 1000° C. allowing very aggressive equivalent oxide thickness (EOT) and inversion layer thickness scaling below 14 Å in a p-metal oxide semiconductor (pMOS) device. | 01-21-2010 |
20100044758 | CMOS WITH CHANNEL P-FINFET AND CHANNEL N-FINFET HAVING DIFFERENT CRYSTALLINE ORIENTATIONS AND PARALLEL FINS - An integrated circuit is fabricated with at least one p-FinFET device and at least one n-FinFET device situated parallel to each other. A first silicon layer having a first crystalline orientation is bonded to a second silicon layer having a second crystalline orientation. The first and second orientations are different from each other. A volume of material is formed that extends through the first layer from the second layer up to the surface of the first layer. The material has a crystalline orientation that substantially matches the orientation of the second layer. Areas of the surface of the first layer that are outside of the region are selectively etched to create a first plurality of fins and areas inside the region to create a second plurality of fins. The etching leaves the first and second pluralities of fins parallel to each other with different surface crystal orientations. | 02-25-2010 |
20100112792 | THICK EPITAXIAL SILICON BY GRAIN REORIENTATION ANNEALING AND APPLICATIONS THEREOF - The invention provides a high temperature (about 1150° C. or greater) annealing process for converting thick polycrystalline Si layers on the order of 1 μm to 40 μm on a single crystal seed layer into thick single crystal Si layers having the orientation of the seed layer, thus allowing production of thick Si films having the quality of single crystal silicon at high rates and low cost of processing. Methods of integrating such high temperature processing into solar cell fabrication are described, with particular attention to process flows in which the seed layer is disposed on a porous silicon release layer. Another aspect pertains to the use of similar high temperature anneals for poly-Si grain growth and grain boundary passivation. A further aspect relates to structures in which these thick single crystal Si films and passivated poly-Si films are incorporated. | 05-06-2010 |
20100203708 | AMORPHIZATION/TEMPLATED RECRYSTALLIZATION METHOD FOR HYBRID ORIENTATION SUBSTRATES - The present invention provides an improved amorphization/templated recrystallization (ATR) method for fabricating low-defect-density hybrid orientation substrates. ATR methods for hybrid orientation substrate fabrication generally start with a Si layer having a first orientation bonded to a second Si layer or substrate having a second orientation. Selected regions of the first Si layer are amorphized and then recrystallized into the orientation of the second Si layer by using the second Si layer as a template. The process flow of the present invention solves two major difficulties not disclosed by prior art ATR methods: the creation of “corner defects” at the edges of amorphized Si regions bounded by trenches, and undesired orientation changes during a high temperature post-recrystallization defect-removal annealing of non-ATR'd regions not bounded by trenches. In particular, this invention provides a process flow comprising the steps of (i) amorphization and low-temperature recrystallization performed in substrate regions free of trenches, (ii) formation of trench isolation regions that subsume the defective regions at the edge of the ATR'd regions, and (iii) a high-temperature defect-removal anneal performed with the trench isolation regions in place. | 08-12-2010 |
20110086473 | HYBRID ORIENTATION SEMICONDUCTOR STRUCTURE WITH REDUCED BOUNDARY DEFECTS AND METHOD OF FORMING SAME - The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template. This optimal arrangement of DSB layer, base substrate, and amorphized region orientation provides a near-vertical, essentially defect-free boundary between original-orientation and changed-orientation silicon regions, thus enabling complete boundary region removal with smaller footprint shallow trench isolation than possible with ATR methods not so optimized. | 04-14-2011 |
20110212622 | SURFACE TEXTURING USING A LOW QUALITY DIELECTRIC LAYER - A low cost method is described for forming a textured Si surface such as for a solar cell which includes forming a dielectric layer containing pinholes, anisotropically etching through the pinholes to form inverted pyramids in the Si surface and removing the dielectric layer thereby producing a high light trapping efficiency for incident radiation. | 09-01-2011 |
20110230030 | STRAIN-PRESERVING ION IMPLANTATION METHODS - An embedded epitaxial semiconductor portion having a different composition than matrix of the semiconductor substrate is formed with a lattice mismatch and epitaxial alignment with the matrix of the semiconductor substrate. The temperature of subsequent ion implantation steps is manipulated depending on the amorphizing or non-amorphizing nature of the ion implantation process. For a non-amorphizing ion implantation process, the ion implantation processing step is performed at an elevated temperature, i.e., a temperature greater than nominal room temperature range. For an amorphizing ion implantation process, the ion implantation processing step is performed at nominal room temperature range or a temperature lower than nominal room temperature range. By manipulating the temperature of ion implantation, the loss of strain in a strained semiconductor alloy material is minimized. | 09-22-2011 |
20120031454 | EFFICIENT NANOSCALE SOLAR CELL AND FABRICATION METHOD - A photovoltaic device and method include a substrate layer having a plurality of structures including peaks and troughs formed therein. A continuous photovoltaic stack is conformally formed over the substrate layer and extends over the peaks and troughs. The photovoltaic stack has a thickness of less than one micron and is configured to transduce incident radiation into current flow. | 02-09-2012 |
20120068267 | STRAINED DEVICES, METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Strained Si and strained SiGe on insulator devices, methods of manufacture and design structures is provided. The method includes growing an SiGe layer on a silicon on insulator wafer. The method further includes patterning the SiGe layer into PFET and NFET regions such that a strain in the SiGe layer in the PFET and NFET regions is relaxed. The method further includes amorphizing by ion implantation at least a portion of an Si layer directly underneath the SiGe layer. The method further includes performing a thermal anneal to recrystallize the Si layer such that a lattice constant is matched to that of the relaxed SiGe, thereby creating a tensile strain on the NFET region. The method further includes removing the SiGe layer from the NFET region. The method further includes performing a Ge process to convert the Si layer in the PFET region into compressively strained SiGe. | 03-22-2012 |
20120104390 | Germanium-Containing Release Layer For Transfer of a Silicon Layer to a Substrate - A germanium-containing layer is deposited on a single crystalline bulk silicon substrate in an ambient including a level of oxygen partial pressure sufficient to incorporate 1%-50% of oxygen in atomic concentration. The thickness of the germanium-containing layer is preferably limited to maintain some degree of epitaxial alignment with the underlying silicon substrate. Optionally, a graded germanium-containing layer can be grown on, or replace, the germanium-containing layer. An at least partially crystalline silicon layer is subsequently deposited on the germanium-containing layer. A handle substrate is bonded to the at least partially crystalline silicon layer. The assembly of the bulk silicon substrate, the germanium-containing layer, the at least partially crystalline silicon layer, and the handle substrate is cleaved within the germanium-containing layer to provide a composite substrate including the handle substrate and the at least partially crystalline silicon layer. Any remaining germanium-containing layer on the composite substrate is removed. | 05-03-2012 |
20120112198 | EPITAXIAL GROWTH OF SILICON CARBIDE ON SAPPHIRE - remove impurities from an exposed surface in the ultrahigh vacuum environment. A high qualify single crystalline or polycrystalline silicon carbide film can be grown directly on the sapphire substrate by chemical vapor deposition employing a silicon-containing reactant and a carbon-containing reactant. Formation of single crystalline silicon carbide has been verified by x-ray diffraction, secondary ion mass spectroscopy, and transmission electron microscopy. | 05-10-2012 |
20120118383 | Autonomous Integrated Circuit - An autonomous integrated circuit (IC) includes a solar cell formed on a bottom substrate of a silicon-on-insulator (SOI) substrate as a handle substrate; an insulating layer of the SOI substrate located on top of the solar cell; and a device layer formed on a top semiconductor layer of the SOI substrate located on top of the insulating layer, wherein a top contact of the device layer is electrically connected to a bottom contact of the solar cell such that the solar cell is enabled to power the device layer. | 05-17-2012 |
20120156861 | QUASI-HYDROPHOBIC Si-Si WAFER BONDING USING HYDROPHILIC Si SURFACES AND DISSOLUTION OF INTERFACIAL BONDING OXIDE - Methods for removing or reducing the thickness of a material layer remaining at Si-Si interfaces after silicon wafer bonding. The methods include an anneal which is performed at a temperature sufficient to dissolve oxide, yet not melt silicon. | 06-21-2012 |
20120216158 | STRAINED DEVICES, METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Strained Si and strained SiGe on insulator devices, methods of manufacture and design structures is provided. The method includes growing an SiGe layer on a silicon on insulator wafer. The method further includes patterning the SiGe layer into PFET and NFET regions such that a strain in the SiGe layer in the PFET and NFET regions is relaxed. The method further includes amorphizing by ion implantation at least a portion of an Si layer directly underneath the SiGe layer. The method further includes performing a thermal anneal to recrystallize the Si layer such that a lattice constant is matched to that of the relaxed SiGe, thereby creating a tensile strain on the NFET region. The method further includes removing the SiGe layer from the NFET region. The method further includes performing a Ge process to convert the Si layer in the PFET region into compressively strained SiGe. | 08-23-2012 |
20120285517 | SCHOTTKY BARRIER SOLAR CELLS WITH HIGH AND LOW WORK FUNCTION METAL CONTACTS - A Schottky Barrier solar cell having at least one of a low work function region and a high work function region provided on the front or back surface of a lightly-doped absorber material, which may be produced in a variety of different geometries. The method of producing the Schottky Barrier solar cells allows for short processing times and the use of low temperatures. | 11-15-2012 |
20120285518 | Solar cell with interdigitated back contacts formed from high and low work-function-tuned silicides of the same metal - A solar cell having n-type and p-type interdigitated back contacts (IBCs), which cover the entire back surface of the absorber layer. The spatial separation of the IBCs is in a direction perpendicular to the back surface, thus providing borderless contacts having a zero-footprint separation. As the contacts are on the back, photons incident on the cell's front surface can be absorbed without any shadowing. | 11-15-2012 |
20120295426 | CMOS WITH CHANNEL P-FINFET AND CHANNEL N-FINFET HAVING DIFFERENT CRYSTALLINE ORIENTATIONS AND PARALLEL FINS - A method for fabricating an integrated circuit with at least one p-FinFET device and at least one n-FinFET device. The method includes bonding a first silicon layer having a first crystalline orientation to a second silicon layer having a second crystalline orientation that is different from the first crystalline orientation. A first plurality of fins and a second plurality of fins are created. A spacer is formed around each fin in the first plurality of fins and second plurality of fins. A set of regions of the second layer between each fin in the first plurality of fins and the second plurality of fins are recessed to form a base with exposed sidewalls under each fin in the first plurality of fins and the second plurality of fins. The base under each fin and a set of exposed regions between each fin is oxidized. | 11-22-2012 |
20120299067 | CMOS WITH CHANNEL P-FINFET AND CHANNEL N-FINFET HAVING DIFFERENT CRYSTALLINE ORIENTATIONS AND PARALLEL FINS - An integrated circuit fabrication apparatus is configured to fabricate an integrated circuit with at least one p-FinFET device and at least one n-FinFET device. A bonding control processor is configured to bond a first silicon layer having a first crystalline orientation to a second silicon layer having a second crystalline orientation that is different from the first crystalline orientation. A material growth processor is configured to form a volume of material extending through the first silicon layer from the second layer up to the surface of first layer. The material has a crystalline orientation that substantially matches the crystalline orientation of second layer. An etching processor is configured to selectively etch areas of the surface of the first layer that are outside of the region to create a first plurality of fins and areas inside the region to create a second plurality of fins. | 11-29-2012 |
20120305929 | BEOL COMPATIBLE FET STRUCTRURE - This invention provides structures and a fabrication process for incorporating thin film transistors in back end of the line (BEOL) interconnect structures. The structures and fabrication processes described are compatible with processing requirements for the BEOL interconnect structures. The structures and fabrication processes utilize existing processing steps and materials already incorporated in interconnect wiring levels in order to reduce added cost associated with incorporating thin film transistors in the these levels. The structures enable vertical (3D) integration of multiple levels with improved manufacturability and reliability as compared to prior art methods of 3D integration. | 12-06-2012 |
20120309269 | LOW-TEMPERATURE METHODS FOR SPONTANEOUS MATERIAL SPALLING - Method to (i) introduce additional control into a material spalling process, thus improving both the crack initiation and propagation, and (ii) increase the range of selectable spalling depths are provided. In one embodiment, the method includes providing a stressor layer on a surface of a base substrate at a first temperature which is room temperature. Next, the base substrate including the stressor layer is brought to a second temperature which is less than room temperature. The base substrate is spalled at the second temperature to form a spalled material layer. Thereafter, the spalled material layer is returned to room temperature, i.e., the first temperature. | 12-06-2012 |
20120326126 | Graphene or Carbon Nanotube Devices with Localized Bottom Gates and Gate Dielectric - Transistor devices having nanoscale material-based channels (e.g., carbon nanotube or graphene channels) and techniques for the fabrication thereof are provided. In one aspect, a transistor device is provided. The transistor device includes a substrate; an insulator on the substrate; a local bottom gate embedded in the insulator, wherein a top surface of the gate is substantially coplanar with a surface of the insulator; a local gate dielectric on the bottom gate; a carbon-based nanostructure material over at least a portion of the local gate dielectric, wherein a portion of the carbon-based nanostructure material serves as a channel of the device; and conductive source and drain contacts to one or more portions of the carbon-based nanostructure material on opposing sides of the channel that serve as source and drain regions of the device. | 12-27-2012 |
20130015455 | GERMANIUM-CONTAINING RELEASE LAYER FOR TRANSFER OF A SILICON LAYER TO A SUBSTRATE - A germanium-containing layer is deposited on a single crystalline bulk silicon substrate in an ambient including a level of oxygen partial pressure sufficient to incorporate 1%-50% of oxygen in atomic concentration. The thickness of the germanium-containing layer is preferably limited to maintain some degree of epitaxial alignment with the underlying silicon substrate. Optionally, a graded germanium-containing layer can be grown on, or replace, the germanium-containing layer. An at least partially crystalline silicon layer is subsequently deposited on the germanium-containing layer. A handle substrate is bonded to the at least partially crystalline silicon layer. The assembly of the bulk silicon substrate, the germanium-containing layer, the at least partially crystalline silicon layer, and the handle substrate is cleaved within the germanium-containing layer to provide a composite substrate including the handle substrate and the at least partially crystalline silicon layer. Any remaining germanium-containing layer on the composite substrate is removed. | 01-17-2013 |
20130126493 | SPALLING WITH LASER-DEFINED SPALL EDGE REGIONS - Laser ablation can be used to form a trench within at least a blanket layer of a stressor layer that is atop a base substrate. A non-ablated portion of the stressor layer has an edge that defines the edge of the material layer region to be spalled. Laser ablation can also be used to form a trench within a blanket material stack including at least a plating seed layer. A stressor layer is formed on the non-ablated portions of the material stack and one portion of the stressor layer has an edge that defines the edge of the material layer region to be spalled. Laser ablation can be further used to form a trench that extends through a blanket stressor layer and into the base substrate itself. The trench has an edge that defines the edge of the material layer region to be spalled. | 05-23-2013 |
20130280885 | LASER-INITIATED EXFOLIATION OF GROUP III-NITRIDE FILMS AND APPLICATIONS FOR LAYER TRANSFER AND PATTERNING - A pulsed laser-initiated exfoliation method for patterning a Group III-nitride film on a growth substrate is provided. This method includes providing a Group III-nitride film a growth substrate, wherein a growth substrate/Group III-nitride film interface is present between the Group III-nitride film and the growth substrate. Next, a laser is selected that provides radiation at a wavelength at which the Group III-nitride film is transparent and the growth substrate is absorbing. The interface is then irradiated with pulsed laser radiation from the Group III-nitride film side of the growth substrate/Group III-nitride film interface to exfoliate a region of the Group III-nitride from the growth substrate. A method for transfer a Group-III nitride film from a growth substrate to a handle substrate is also provided. | 10-24-2013 |
20130313683 | SEMICONDUCTOR WIRE-ARRAY VARACTOR STRUCTURES - Semiconductor variable capacitor (varactor) devices are provided, which are formed with an array of radial p-n junction structures to provide improved dynamic range and sensitivity. For example, a semiconductor varactor device includes a doped semiconductor substrate having first and second opposing surfaces and an array of pillar structures formed on the first surface of the doped semiconductor substrate. Each pillar structure includes a radial p-n junction structure. A first metallic contact layer is conformally formed over the array of pillar structures on the first surface of the doped semiconductor substrate. A second metallic contact layer formed on the second surface of the doped semiconductor substrate. An insulating layer is formed on the doped semiconductor substrate surrounding the array of pillar structures. | 11-28-2013 |
20130316512 | SEMICONDUCTOR WIRE-ARRAY VARACTOR STRUCTURES - Semiconductor variable capacitor (varactor) devices are provided, which are formed with an array of radial p-n junction structures to provide improved dynamic range and sensitivity. For example, a semiconductor varactor device includes a doped semiconductor substrate having first and second opposing surfaces and an array of pillar structures formed on the first surface of the doped semiconductor substrate. Each pillar structure includes a radial p-n junction structure. A first metallic contact layer is conformally formed over the array of pillar structures on the first surface of the doped semiconductor substrate. A second metallic contact layer formed on the second surface of the doped semiconductor substrate. An insulating layer is formed on the doped semiconductor substrate surrounding the array of pillar structures. | 11-28-2013 |
20130316538 | SURFACE MORPHOLOGY GENERATION AND TRANSFER BY SPALLING - The generation of surface patterns or the replication of surface patterns is achieved in the present disclosure without the need to employ an etching process. Instead, a unique fracture mode referred to as spalling is used in the present disclosure to generate or replicate surface patterns. In the case of surface pattern generation, a surface pattern is provided in a stressor layer and then spalling is performed. In the case of surface pattern replication, a surface pattern is formed within or on a surface of a base substrate, and then a stressor layer is applied. After applying the stressor layer, spalling is performed. Generation or replication of surface patterns utilizing spalling provides a low cost means for generation or replication of surface patterns. | 11-28-2013 |
20140027058 | CMOS WITH CHANNEL P-FINFET AND CHANNEL N-FINFET HAVING DIFFERENT CRYSTALLINE ORIENTATIONS AND PARALLEL FINS - An integrated circuit fabrication apparatus is configured to fabricate an integrated circuit with at least one p-FinFET device and at least one n-FinFET device. A bonding control processor is configured to bond a first silicon layer having a first crystalline orientation to a second silicon layer having a second crystalline orientation that is different from the first crystalline orientation. A material growth processor is configured to form a volume of material extending through the first silicon layer from the second layer up to the surface of first layer. The material has a crystalline orientation that substantially matches the crystalline orientation of second layer. An etching processor is configured to selectively etch areas of the surface of the first layer that are outside of the region to create a first plurality of fins and areas inside the region to create a second plurality of fins. | 01-30-2014 |
20140034699 | METHOD FOR IMPROVING QUALITY OF SPALLED MATERIAL LAYERS - Methods for removing a material layer from a base substrate utilizing spalling in which mode III stress, i.e., the stress that is perpendicular to the fracture front created in the base substrate, during spalling is reduced. The substantial reduction of the mode III stress during spalling results in a spalling process in which the spalled material has less surface roughness at one of its' edges as compared to prior art spalling processes in which the mode III stress is present and competes with spalling. | 02-06-2014 |
20140035008 | CMOS WITH CHANNEL P-FINFET AND CHANNEL N-FINFET HAVING DIFFERENT CRYSTALLINE ORIENTATIONS AND PARALLEL FINS - An integrated circuit includes at least one single-crystal fin having a first crystal orientation. The integrated circuit also includes at least one single-crystal fin having a second crystal orientation. The single-crystal fin having the first crystal orientation and the single-crystal fin having the second crystal orientation are substantially parallel. | 02-06-2014 |
20140096820 | Laser Doping of Crystalline Semiconductors Using a Dopant-Containing Amorphous Silicon Stack For Dopant Source and Passivation - Techniques and structures for laser doping of crystalline semiconductors using a dopant-containing amorphous silicon stack for dopant source and passivation. A structure includes a crystalline semiconductor having at least one surface, a doped crystalline region disposed in at least one selected area of the semiconductor surface, and a dopant-containing amorphous silicon layer stack containing a same dopant as present in the doped crystalline region on at least a portion of the semiconductor surface outside the selected area, wherein the dopant-containing amorphous silicon layer stack passivates the portion of the semiconductor surface on which it is disposed. | 04-10-2014 |
20140099780 | Laser Doping of Crystalline Semiconductors Using a Dopant-Containing Amorphous Silicon Stack For Dopant Source and Passivation - Techniques and structures for laser doping of crystalline semiconductors using a dopant-containing amorphous silicon stack for dopant source and passivation. A method includes forming a dopant-containing amorphous silicon layer stack on at least one portion of a surface of a crystalline semiconductor layer, and irradiating a selected area of the dopant-containing amorphous silicon layer stack, wherein the selected area of the dopant-containing amorphous silicon layer stack interacts with an upper portion of the underlying crystalline semiconductor layer to form a doped, conductive crystalline region, and each non-selected area of the dopant-containing amorphous silicon layer stack remains intact on the at least one portion of the surface of the crystalline semiconductor layer. | 04-10-2014 |
20140183686 | AUTONOMOUS INTEGRATED CIRCUITS - An autonomous integrated circuit (IC) includes a solar cell formed on a bottom substrate of a silicon-on-insulator (SOI) substrate as a handle substrate; an insulating layer of the SOI substrate located on top of the solar cell; and a device layer formed on a top semiconductor layer of the SOI substrate located on top of the insulating layer, wherein a top contact of the device layer is electrically connected to a bottom contact of the solar cell such that the solar cell is enabled to power the device layer. | 07-03-2014 |
20140242746 | ELECTRODE FORMATION FOR HETEROJUNCTION SOLAR CELLS - A method for forming a photovoltaic device includes forming a doped layer on a crystalline substrate, the doped layer having an opposite dopant conductivity as the substrate. A non-crystalline transparent conductive electrode (TCE) layer is formed on the doped layer at a temperature less than 150 degrees Celsius. The TCE layer is flash annealed to crystallize material of the TCE layer at a temperature above about 150 degrees Celsius for less than 10 seconds. | 08-28-2014 |
20140315389 | CRACK CONTROL FOR SUBSTRATE SEPARATION - A method for separating a layer for transfer includes forming a crack guiding layer on a substrate and forming a device layer on the crack-guiding layer. The crack guiding layer is weakened by exposing the crack-guiding layer to a gas which reduces adherence at interfaces adjacent to the crack guiding layer. A stress inducing layer is formed on the device layer to assist in initiating a crack through the crack guiding layer and/or the interfaces. The device layer is removed from the substrate by propagating the crack. | 10-23-2014 |
20140374702 | CARBON NANOSTRUCTURE DEVICE FABRICATION UTILIZING PROTECT LAYERS - Hall effect devices and field effect transistors are formed incorporating a carbon-based nanostructure layer such as carbon nanotubes and/or graphene with a sacrificial metal layer formed there over to protect the carbon-based nanostructure layer during processing. | 12-25-2014 |
20150060856 | BEOL COMPATIBLE FET STRUCTURE - This invention provides structures and a fabrication process for incorporating thin film transistors in back end of the line (BEOL) interconnect structures. The structures and fabrication processes described are compatible with processing requirements for the BEOL interconnect structures. The structures and fabrication processes utilize existing processing steps and materials already incorporated in interconnect wiring levels in order to reduce added cost associated with incorporating thin film transistors in the these levels. The structures enable vertical (3D) integration of multiple levels with improved manufacturability and reliability as compared to prior art methods of 3D integration. | 03-05-2015 |