Abstract: A silicon-on-insulator device has a localized biasing structure formed in the insulator layer of the SOI. The localized biasing structure includes a patterned conductor that provides a biasing signal to distinct regions of the silicon layer of the SOI. The conductor is recessed into the insulator layer to provide a substantially planar interface with the silicon layer. The conductor is connected to a bias voltage source. In an embodiment, a plurality of conductor is provided that respectively connected to a plurality of voltage sources. Thus, different regions of the silicon layer are biased by different bias signals.

Abstract: Device structures with a reduced junction area in an SOI process, methods of making the device structures, and design structures for a lateral diode. The device structure includes one or more dielectric regions, such as STI regions, positioned in the device region and intersecting the p-n junction between an anode and cathode. The dielectric regions, which may be formed using shallow trench isolation techniques, function to reduce the width of a p-n junction with respect to the width area of the cathode at a location spaced laterally from the p-n junction and the anode. The width difference and presence of the dielectric regions creates an asymmetrical diode structure. The volume of the device region occupied by the dielectric regions is minimized to preserve the volume of the cathode and anode.

Abstract: Disclosed is a silicon-on-insulator-based Schottky barrier diode with a low forward voltage that can be manufactured according to standard SOI process flow. An active silicon island is formed using an SOI wafer. One area of the island is heavily-doped with an n-type or p-type dopant, one area is lightly-doped with the same dopant, and an isolation structure is formed on the top surface above a junction between the two areas. A metal silicide region contacts the lightly-doped side of the island forming a Schottky barrier. Another discrete metal silicide region contacts the heavily-doped area of the island forming an electrode to the Schottky barrier (i.e., a Schottky barrier contact). The two metal silicide regions are isolated from each other by the isolation structure. Contacts to each of the discrete metal silicide regions allow a forward and/or a reverse bias to be applied to the Schottky barrier.

Abstract: Semiconductor structures including parallel graphene nanoribbons or carbon nanotubes oriented along crystallographic directions are provided from a template of silicon carbide (SiC) fins or nanowires. The SiC fins or nanowires are first provided and then graphene nanoribbons or carbon nanotubes are formed on the exposed surfaces of the fin or the nanowires by annealing. In embodiments in which closed carbon nanotubes are formed, the nanowires are suspended prior to annealing. The location, orientation and chirality of the graphene nanoribbons and the carbon nanotubes that are provided are determined by the corresponding silicon carbide fins and nanowires from which they are formed.

Abstract: A method for fabricating an integrated circuit having a FinFET structure includes providing a semiconductor substrate comprising silicon and a high carrier mobility material, forming one or more fin structures on the semiconductor substrate, and subjecting the substrate to a condensation process for the condensation of the high carrier mobility material. The condensation process results in the formation of condensed fin structures formed substantially entirely of the high carrier mobility material and a layer of silicon oxide formed over the condensed fin structures. The method further includes removing the silicon oxide formed over the condensed fin structures so as to expose the condensed fin structures.

Abstract: A process for avoiding formation of a Si—SiO2—H2 environment during a dissolution treatment of a semiconductor-on-insulator structure that includes a carrier substrate, an oxide layer, a thin layer of semiconductor material and a peripheral ring in which the oxide layer is exposed. This process includes encapsulating at least the exposed oxide layer of the peripheral ring with semiconductor material by performing a creep thermal treatment; and performing an oxide dissolution treatment to reduce part of the thickness of the oxide layer. In this process, the semiconductor material that encapsulates the oxide layer has a thickness before the oxide dissolution that is at least twice that of the oxide that is to be dissolved, thus avoiding formation of a Si—SiO2—H2 environment on the peripheral ring where the oxide layer would otherwise be exposed.

Abstract: Methods are disclosed to fabricate a transistor, for example a FinFET, by forming over a substrate at least one electrically conductive channel between a source region and a drain region; forming a gate structure to be disposed over a portion of the channel, the gate structure having a width and a length and a height defining two opposing sidewalls of the gate structure and being formed such that the channel said passes through the sidewalls; forming spacers on the sidewalls; forming a layer of epitaxial silicon over the channel; removing the spacers; and forming a dielectric layer to be disposed over the gate structure and portions of the channel that are external to the gate structure such that a capacitance-reducing air gap underlies the dielectric layer and is disposed adjacent to the sidewalls of said gate structure in a region formerly occupied by the spacers.

Abstract: Embodiments of the invention provide a method of forming nickel-silicide. The method may include depositing first and second metal layers over at least one of a gate, a source, and a drain region of a field-effect-transistor (FET) through a physical vapor deposition (PVD) process, wherein the first metal layer is deposited using a first nickel target material containing platinum (Pt), and the second metal layer is deposited on top of the first metal layer using a second nickel target material containing no or less platinum than that in the first nickel target material; and annealing the first and second metal layers covering the FET to form a platinum-containing nickel-silicide layer at a top surface of the gate, source, and drain regions.

Abstract: A method of actuating a semiconductor device includes providing a transistor including a substrate and a first electrically conductive material layer stack positioned on the substrate. The first electrically conductive material layer stack includes a reentrant profile. A second electrically conductive material layer includes first and second discrete portions in contact with first and second portions of a semiconductor material layer that conforms to the reentrant profile and is in contact with an electrically insulating material layer that conforms to the reentrant profile. A voltage is applied between the first discrete portion and the second discrete portion of the second electrically conductive material layer. A voltage is applied to the first electrically conductive material layer stack to modulate a resistance between the first discrete portion and the second discrete portion of the second electrically conductive material layer.

Abstract: A circuit board includes: a first wiring layer provided on a substrate; an insulating layer including an opening, the insulating layer being provided on the first wiring layer; a surface-energy control layer provided in a region opposed to the opening of the insulating layer on the first wiring layer, the surface-energy control layer controlling surface energy of the first wiring layer; a semiconductor layer provided in a selective region on the insulating layer; and a second wiring layer on the insulating layer, the second wiring layer being electrically connected to the semiconductor layer, and being electrically connected to the first wiring layer through the opening.

Abstract: An object is to provide a semiconductor device of which a manufacturing process is not complicated and by which cost can be suppressed, by forming a thin film transistor using an oxide semiconductor film typified by zinc oxide, and a manufacturing method thereof. For the semiconductor device, a gate electrode is formed over a substrate; a gate insulating film is formed covering the gate electrode; an oxide semiconductor film is formed over the gate insulating film; and a first conductive film and a second conductive film are formed over the oxide semiconductor film. The oxide semiconductor film has at least a crystallized region in a channel region.

Abstract: Embodiments of the present invention provide a method of forming fin-type transistors having replace-gate electrodes with self-aligned diffusion contacts. The method includes forming one or more silicon fins on top of an oxide layer, the oxide layer being situated on top of a silicon donor wafer; forming one or more dummy gate electrodes crossing the one or more silicon fins; forming sidewall spacers next to sidewalls of the one or more dummy gate electrodes; removing one or more areas of the oxide layer thereby creating openings therein, the openings being self-aligned to edges of the one or more fins and edges of the sidewall spacers; forming an epitaxial silicon layer in the openings; removing the donor wafer; and siliciding at least a bottom portion of the epitaxial silicon layer. A semiconductor structure formed thereby is also provided.

Abstract: This application relates to graphene based heterostructures and methods of making graphene based heterostructures. The graphene heterostructures comprise: i) a first encapsulation layer; ii) a second encapsulation layer; and iii) a graphene layer. The heterostructures find application in electronic devices.

Abstract: A method of forming a template on a silicon substrate includes providing a single crystal silicon substrate. The method further includes forming an aluminum oxide coating on the surface of the silicon substrate, the aluminum oxide being substantially crystal lattice matched to the surface of the silicon substrate and epitaxially depositing a layer of aluminum nitride (AlN) on the aluminum oxide coating substantially crystal lattice matched to the surface of the aluminum nitride.

Abstract: There is provided a novel composition for forming a gate insulating film taking into consideration also electrical characteristics after other processes such as wiring by irradiation with an ultraviolet ray and the like during the production of an organic transistor using a gate insulating film. A composition for forming a gate insulating film for a thin-film transistor comprising: a component (i): an oligomer compound or a polymer compound containing a repeating unit having a structure in which a nitrogen atom of a triazine-trione ring is bonded to a nitrogen atom of another triazine-trione ring through a hydroxyalkylene group; and a component (ii): a compound having two or more blocked isocyanate groups in one molecule thereof.

Abstract: Disclosed is semiconductor structure with an insulator layer on a semiconductor substrate and a device layer is on the insulator layer. The substrate is doped with a relatively low dose of a dopant having a given conductivity type such that it has a relatively high resistivity. Additionally, a portion of the semiconductor substrate immediately adjacent to the insulator layer can be doped with a slightly higher dose of the same dopant, a different dopant having the same conductivity type or a combination thereof. Optionally, micro-cavities are created within this same portion so as to balance out any increase in conductivity due to increased doping with a corresponding increase in resistivity. Increasing the dopant concentration at the semiconductor substrate-insulator layer interface raises the threshold voltage (Vt) of any resulting parasitic capacitors and, thereby reduces harmonic behavior. Also disclosed herein are embodiments of a method for forming such a semiconductor structure.

Abstract: A semiconductor structure includes a semiconductor fin on a top surface of a substrate, wherein the semiconductor fin includes a middle section having a first width; and a first and a second end section connected to opposite ends of the middle section, wherein the first and the second end sections each comprises at least a top portion having a second width greater than the first width. The semiconductor structure further includes a gate dielectric layer on a top surface and sidewalls of the middle section of the semiconductor fin; and a gate electrode on the gate dielectric layer.

Abstract: The invention relates to finishing a substrate of the semiconductor-on-insulator (SeOI) type comprising an insulator layer buried between two semiconducting material layers. The method successively comprises routing the annular periphery of the substrate so as to obtain a routed substrate, and encapsulating the routed substrate so as to cover the routed side edge of the buried insulator layer by means of a semiconducting material.

Abstract: The present invention relates to a method for producing a modified surface of a substrate that stimulates the growth of epitaxial layers of group-III nitride semiconductors with substantially improved structural perfection and surface flatness. The modification is conducted outside or inside a growth reactor by exposing the substrate to a gas-product of the reaction between hydrogen chloride (HCl) and aluminum metal (Al). As a single-step or an essential part of the multi-step pretreatment procedure, the modification gains in coherent coordination between the substrate and group-III nitride epitaxial structure to be deposited. Along with epilayer, total epitaxial structure may include buffer inter-layer to accomplish precise substrate-epilayer coordination.

Abstract: A nanocrystal includes a core including a Group III-V semiconductor and a transition metal alloyed with the Group III-V semiconductor, wherein the transition metal is present at a higher molar concentration in an outermost surface layer of the core than in a central portion of the core.

Abstract: A composite substrate having silicon substrate with excellent crystallinity and a method of manufacturing the composite substrate and an electronic component using the composite substrate are provided. A composite substrate (1) is configured to bond a support substrate (10) having electrical insulating property, and a silicon substrate (20) which is overlaid on the support substrate (10). The semiconductor substrate (20) of the composite substrate (1) includes a plurality of first regions (20x) in which a device function unit functioning as a semiconductor device is formed, and a second region (20y) located between these first regions (20x). In the semiconductor substrate (20) of the composite substrate (1), an amorphous form (22) containing silicon and a metal is present in the second region (20y).

Abstract: It is an object to provide a thin film transistor having favorable electric characteristics and high reliability and a semiconductor device which includes the thin film transistor as a switching element. An In—Ga—Zn—O-based film having an incubation state that shows an electron diffraction pattern, which is different from a conventionally known amorphous state where a halo shape pattern appears and from a conventionally known crystal state where a spot appears clearly, is formed. The In—Ga—Zn—O-based film having an incubation state is used for a channel formation region of a channel etched thin film transistor.

Abstract: At present, a forming process of a base film through an amorphous silicon film is conducted in respective film forming chambers in order to obtain satisfactory films. When continuous formation of the base film through the amorphous silicon film is performed in a single film forming chamber with the above film formation condition, crystallization is not sufficiently attained in a crystallization process. By forming the amorphous silicon film using silane gas diluted with hydrogen, crystallization is sufficiently attained in the crystallization process even with the continuous formation of the base film through the amorphous silicon film in the single film forming chamber.

Abstract: A release layer formed over a substrate; at least one of thin film integrated circuits is formed over the release layer; a film is formed over each of the at least one of thin film integrated circuits; and the release layer is removed by using an etchant; thus, the at least one of thin film integrated circuits is peeled from the substrate. A semiconductor device is formed by sealing the peeled thin film integrated circuit by lamination or the like.

Abstract: In a method of forming an active pattern, a gate metal layer is formed on a base substrate. The gate metal layer is patterned to form a gate line, and a gate pattern spaced apart from the gate line. A gate insulation layer is formed on the base substrate including the gate line and the gate pattern thereon, to form a first protruded boundary surface corresponding to an area including the gate pattern. An amorphous semiconductor layer is formed on the base substrate including the gate insulation layer thereon, to form a second protruded boundary surface corresponding to the first protruded boundary surface. The amorphous semiconductor layer is crystallized by illuminating a laser to the amorphous semiconductor layer on the second protruded boundary surface.

Abstract: A dichalcogenobenzodipyrrole compound represented by the formula (1): (wherein, X and Y represent each independently a sulfur atom, an oxygen atom, a selenium atom, a tellurium atom or SO2. R1 to R8 represent each independently a hydrogen atom, a halogen atom, an alkyl group having 1 to 30 carbon atoms, an alkoxy group having 1 to 30 carbon atoms, an alkenyl group having 2 to 30 carbon atoms, an alkynyl group having 2 to 30 carbon atoms, an alkylthio group having 1 to 30 carbon atoms, an aryl group having 6 to 30 carbon atoms or a heteroaryl group having 4 to 30 carbon atoms and the like.) is utilizable in an organic semiconductor device having high carrier mobility.

Abstract: Methods of depositing epitaxial material using a repeated deposition and etch process. The deposition and etch processes can be repeated until a desired thickness of silicon-containing material is achieved. During the deposition process, a doped silicon film can be deposited. The doped silicon film can be selectively deposited in a trench on a substrate. The trench can have a liner comprising silicon and carbon prior to depositing the doped silicon film. The doped silicon film may also contain germanium. Germanium can promote uniform dopant distribution within the doped silicon film.

Abstract: A three-dimensional (3D) non-volatile memory (NVM) array including spaced-apart horizontally-disposed bitline structures arranged in vertical stacks, each bitline structures including a mono-crystalline silicon beam and a charge storage layer entirely surrounding the beam. Vertically-oriented wordline structures are disposed next to the stacks such that each wordline structure contacts corresponding portions of the charge storage layers. NVM memory cells are formed at each bitline/wordline intersection, with corresponding portions of each bitline structure forming each cell's channel region. The bitline structures are separated by air gaps, and each charge storage layer includes a high-quality thermal oxide layer that entirely covers (i.e., is formed on the upper, lower and opposing side surfaces of) each of the mono-crystalline silicon beams.

Abstract: The present invention provides a SOI substrate that can realize a composite device formed of a MOS integrated circuit and a passive device and can reduce a size and a manufacturing cost of a semiconductor device. There is provided a fiber SOI substrate 5 comprising a fiber 1 with a polygonal cross section, and a semiconductor thin film 3 crystallized after film formation on at least one surface of the fiber 1, and a plurality of grooves 8 that extend in a linear direction of the fiber 1 and are arranged at intervals in a width direction are formed on a surface of the fiber 1.

Abstract: Semiconductor devices having modulated nanowire counts and methods to form such devices are described. For example, a semiconductor structure includes a first semiconductor device having a plurality of nanowires disposed above a substrate and stacked in a first vertical plane with a first uppermost nanowire. A second semiconductor device has one or more nanowires disposed above the substrate and stacked in a second vertical plane with a second uppermost nanowire. The second semiconductor device includes one or more fewer nanowires than the first semiconductor device. The first and second uppermost nanowires are disposed in a same plane orthogonal to the first and second vertical planes.

Abstract: Embodiments of the invention provide a crystalline aluminum carbide layer, a laminate substrate having the crystalline aluminum carbide layer formed thereon, and a method of fabricating the same. The laminate substrate has a GaN layer including a GaN crystal and an AlC layer including an AlC crystal. Further, the method of fabricating the laminate substrate, which has the AlN layer including the AlN crystal and the AlC layer including the AlC crystal, includes supplying a carbon containing gas and an aluminum containing gas to grow the AlC layer.

Abstract: A semiconductor device is provided comprising a bilayer graphene comprising a first and a second adjacent graphene layer, and a first electrically insulating layer contacting the first graphene layer, the first electrically insulating layer comprising an electrically insulating material, and a substance suitable for creating free charge carriers of a first type in the first graphene layer, the semiconductor device further comprising an electrically insulating region contacting the second graphene layer and suitable for creating free charge carriers of a second type, opposite to the first type, in the second graphene layer.

Abstract: Provided is a method for manufacturing a semiconductor light-emitting element having a narrow wavelength distribution and comprising a substrate and a group III compound semiconductor layer formed thereon, the substrate being made of a material different from the compound semiconductor constituting the semiconductor layer. The method for manufacturing a semiconductor light-emitting element having a group III compound semiconductor layer is characterized by comprising a semiconductor layer-forming step wherein a group III compound semiconductor layer having a total thickness of not less than 8 ?m is formed on a substrate (11) having a diameter D, a thickness and an amount of warpage H within the range of ±30 ?m. The method is also characterized in that the diameter D and the thickness d of the substrate (11) satisfy the following formula (1): 0.7×102?(D/d)?1.5×102??(1).

Abstract: A method for fabricating a nonvolatile memory device includes forming a stacked structure having a plurality of interlayer dielectric layers and a plurality of sacrificial layers wherein interlayer dielectric layers and sacrificial layers are alternately stacked over a substrate, forming a first hole exposing a part of the substrate by selectively etching the stacked structure, forming a first insulation layer in the first hole, forming a second hole exposing the part of the substrate by selectively etching the first insulation layer, and forming a channel layer in the second hole.

Abstract: A GaN-based semiconductor is epitaxially grown on a silicon substrate with a surface orientation of (111). The difference between the lattice constant of the GaN and the silicon (111) surface is approximately 17%, which is quite large. Therefore, the dislocation density of the grown GaN exceeds 1010 cm?2. Screw dislocation density causes the leak current of the transistor using GaN to increases. Furthermore, the mobility of the transistor is reduced. Provided is a semiconductor substrate comprising a silicon substrate and a nitride semiconductor layer that is epitaxially grown on a (150) surface of the silicon substrate.

Abstract: Illustrative embodiments of power amplifiers and associated methods are disclosed. In at least one embodiment, a method may include fabricating a power amplifier in a first silicon layer of a silicon-on-insulator (SOI) substrate, wherein the SOI substrate comprises the first silicon layer, a second silicon layer, and a buried oxide layer disposed between the first and second silicon layers; removing at least some of the second silicon layer from the SOI substrate, after fabricating the power amplifier; and securing the SOI substrate, after removing at least some of the second silicon layer, to an electrically non-conductive and thermally conductive substrate.

Abstract: A method is provided for controlling the channel length in a thin-film transistor (TFT). The method forms a printed ink first source/drain (S/D) structure overlying a substrate. A fluoropolymer mask is deposited to cover the first S/D structure. A boundary region is formed between the edge of the fluoropolymer mask and the edge of the printed ink first S/D structure, having a width. Then, a primary ink is printed at least partially overlying the boundary region, forming a printed ink second S/D structure, having an edge adjacent to the fluoropolymer mask edge. After removing the fluoropolymer mask, the printed ink first S/D structure edge is left separated from the printed ink second S/D structure edge by a space equal to the boundary region width. A semiconductor channel is formed partially overlying the first and second S/D structures, having a channel length equal to the boundary region width.

Abstract: A two-step hydrogen anneal process has been developed for use in fabricating semiconductor nanowires for use in non-planar semiconductor devices. In the first part of the two-step hydrogen anneal process, which occurs prior to suspending a semiconductor nanowire, the initial roughness of at least the sidewalls of the semiconductor nanowire is reduced, while having at least the bottommost surface of the nanowire pinned to an uppermost surface of a substrate. After performing the first hydrogen anneal, the semiconductor nanowire is suspended and then a second hydrogen anneal is performed which further reduces the roughness of all exposed surfaces of the semiconductor nanowire and reshapes the semiconductor nanowire. By breaking the anneal into two steps, smaller semiconductor nanowires at a tight pitch survive the process and yield.

Abstract: Shallow trenches are formed around a vertical stack of a buried insulator portion and a top semiconductor portion. A dielectric material layer is deposited directly on sidewalls of the top semiconductor portion. Shallow trench isolation structures are formed by filling the shallow trenches with a dielectric material such as silicon oxide. After planarization, the top semiconductor portion is laterally contacted and surrounded by the dielectric material layer. The dielectric material layer prevents exposure of the handle substrate underneath the buried insulator portion during wet etches, thereby ensuring electrical isolation between the handle substrate and gate electrodes subsequently formed on the top semiconductor portion.

Abstract: Methods, structures and devices are provided in which a crystalline silicon surface is passivated by an ultra-thin silicon oxide layer and an outer passivating dielectric layer, where the ultra-thin silicon oxide layer has a thickness on an Angstrom scale. In some embodiments, both layers are formed by low temperature processes. The outer passivating layer may be formed according to a PECVD process that employs hydrogen-containing precursor gases, such that hydrogen is incorporated into one or both of the silicon oxide layer and the passivating dielectric layer. The present methods may be employed for the passivation of a wide variety of structures and devices, including photovoltaic cells, MOSFET devices, flash memory devices, and thin-film silicon substrates that may contain such devices.

Abstract: Hybrid nanowire FET and FinFET devices and methods for fabrication thereof are provided. In one aspect, a method for fabricating a CMOS circuit having a nanowire FET and a finFET includes the following steps. A wafer is provided having an active layer over a BOX. A first region of the active layer is thinned. An organic planarizing layer is deposited on the active layer. Nanowires and pads are etched in the first region of the active layer using a first hardmask. The nanowires are suspended over the BOX. Fins are etched in the second region of the active layer using a second hardmask. A first gate stack is formed that surrounds at least a portion of each of the nanowires. A second gate stack is formed covering at least a portion of each of the fins. An epitaxial material is grown on exposed portions of the nanowires, pads and fins.

Abstract: A double gate metal-oxide semiconductor field-effect transistor (MOSFET) includes a fin, a first gate and a second gate. The first gate is formed on top of the fin. The second gate surrounds the fin and the first gate. In another implementation, a triple gate MOSFET includes a fin, a first gate, a second gate, and a third gate. The first gate is formed on top of the fin. The second gate is formed adjacent the fin. The third gate is formed adjacent the fin and opposite the second gate.

Abstract: The present invention discloses a method of fabricating high-mobility dual channel material based on SOI substrate, wherein compressive strained SiGe is epitaxially grown on a conventional SOI substrate to be used as channel material of PMOSFET; Si is then epitaixally grown on SiGe, and approaches such as ion implantation and annealing are employed to allow relaxation of part of strained SiGe and transfer strain to the Si layer thereon so as to form strained Si material as channel material of NMOSFET. With simple process and easy realization, this method can provide high-mobility channel material for NMOSFET and PMOSFET at the same time, well meeting the requirement of simultaneously enhancing the performance of NMOSFET and PMOSFET devices and therefore providing potential channel material for CMOS process of the next generation.

Abstract: Techniques for fabricating a field effect transistor (FET) device having a doped core and an undoped or counter-doped epitaxial shell are provided. In one aspect, a method of fabricating a FET device is provided. The method includes the following steps. A wafer is provided having a semiconductor material selected from the group consisting of silicon, silicon germanium and silicon carbon. At least one fin core is formed in the wafer. Ion implantation is used to dope the fin core. Corners of the fin core are reshaped to make the corners rounded or faceted. An epitaxial shell is grown surrounding the fin core, wherein the epitaxial shell includes a semiconductor material selected from the group consisting of silicon, silicon germanium and silicon carbon.

Abstract: The invention relates to a GaN-crystal free-standing substrate obtained from a GaN crystal grown by HVPE with a (0001) plane serving as a crystal growth plane and at least one plane of a {10-11} plane and a {11-22} plane serving as a crystal growth plane that constitutes a facet crystal region, except for the side surface of the crystal, wherein the (0001)-plane-growth crystal region has a carbon concentration of 5×1016 atoms/cm3 or less, a silicon concentration of 5×1017 atoms/cm3 or more and 2×1018 atoms/cm3 or less, and an oxygen concentration of 1×1017 atoms/cm3 or less; and the facet crystal region has a carbon concentration of 3×1016 atoms/cm3 or less, a silicon concentration of 5×1017 atoms/cm3 or less, and an oxygen concentration of 5×1017 atoms/cm3 or more and 5×1018 atoms/cm3 or less.

Abstract: A two-step hydrogen anneal process has been developed for use in fabricating semiconductor nanowires for use in non-planar semiconductor devices. In the first part of the two-step hydrogen anneal process, which occurs prior to suspending a semiconductor nanowire, the initial roughness of at least the sidewalls of the semiconductor nanowire is reduced, while having at least the bottommost surface of the nanowire pinned to an uppermost surface of a substrate. After performing the first hydrogen anneal, the semiconductor nanowire is suspended and then a second hydrogen anneal is performed which further reduces the roughness of all exposed surfaces of the semiconductor nanowire and reshapes the semiconductor nanowire. By breaking the anneal into two steps, smaller semiconductor nanowires at a tight pitch survive the process and yield.

Abstract: A single crystalline silicon carbide layer can be grown on a single crystalline sapphire substrate. Subsequently, a graphene layer can be formed by conversion of a surface layer of the single crystalline silicon layer during an anneal at an elevated temperature in an ultrahigh vacuum environment. Alternately, a graphene layer can be deposited on an exposed surface of the single crystalline silicon carbide layer. A graphene layer can also be formed directly on a surface of a sapphire substrate or directly on a surface of a silicon carbide substrate. Still alternately, a graphene layer can be formed on a silicon carbide layer on a semiconductor substrate. The commercial availability of sapphire substrates and semiconductor substrates with a diameter of six inches or more allows formation of a graphene layer on a commercially scalable substrate for low cost manufacturing of devices employing a graphene layer.

Abstract: Device structures, design structures, and fabrication methods for fin-type field-effect transistor integrated circuit technologies. First and second fins, which constitute electrodes of the device structure, are each comprised of a first semiconductor material. The second fin is formed adjacent to the first fin to define a gap separating the first and second fins. Positioned in the gap is a layer comprised of a second semiconductor material.

Abstract: An organic film-forming polymer has a Tg of at least 70° C. and comprises a backbone comprising recurring units of Structure (A) shown in this application. These organic film-forming polymers can be used as dielectric materials in various devices with improved properties such as improved mobility.

Abstract: A thin-body SOI CMOS structure and method for fabricating thin-body SOI CMOS structures with Si channels for NFETs and SiGe/Si or SiGe channels for PFETs. The CMOS structure imparts beneficial channel stress to PFETs while not degrading NFETs and leading to beneficial higher gate capacitance for PFETs.