Abstract: Vertical devices and methods of forming the same are provided. One example method of forming a vertical device can include forming a trench in a semiconductor structure, and partially filling the trench with an insulator material. A dielectric material is formed over the insulator material. The dielectric material is modified into a modified dielectric material having an etch rate greater than an etch rate of the insulator material. The modified dielectric material is removed from the trench via a wet etch.

Abstract: A method of creating a trench having a portion of a bulb-shaped cross-section in silicon is disclosed. The method comprises forming at least one trench in silicon and forming a liner in the at least one trench. The liner is removed from a bottom surface of the at least one trench to expose the underlying silicon. A portion of the underlying exposed silicon is removed to form a cavity in the silicon. At least one removal cycle is conducted to remove exposed silicon in the cavity to form a bulb-shaped cross-sectional profile, with each removal cycle comprising subjecting the silicon in the cavity to ozonated water to oxidize the silicon and subjecting the oxidized silicon to a hydrogen fluoride solution to remove the oxidized silicon. A semiconductor device structure comprising the at least one trench comprising a cavity with a bulb-shaped cross-sectional profile is also disclosed.

Abstract: A semiconductor structure is provided in the present invention. The semiconductor structure includes a substrate, a first material layer and a second material layer. A trench region is defined on the substrate. The trench region includes two separated first regions and a second region, wherein the second region is adjacent to and between the two first regions. The first material layer is disposed on the substrate outside the trench region. The second material layer is disposed in the second region and is level with the first material layer.

Abstract: Provided is a biological component detection device with which a biological component can be detected at high sensitivity by using an InP-based photodiode in which a dark current is reduced without using a cooling mechanism and the sensitivity is extended to a wavelength of 1.8 ?m or more. An absorption layer 3 has a multiple quantum well structure composed of group III-V semiconductors, a pn-junction 15 is formed by selectively diffusing an impurity element in the absorption layer, and the concentration of the impurity element in the absorption layer is 5×1016/cm3 or less, the diffusion concentration distribution control layer has an n-type impurity concentration of 2×1015/cm3 or less before the diffusion, the diffusion concentration distribution control layer having a portion adjacent to the absorption layer, the portion having a low impurity concentration.

Abstract: The present invention discloses a semiconductor device and a manufacturing method thereof. The method comprises the steps of providing a substrate on which a graphene layer or carbon nanotube layer is formed; exposing part of the graphene layer or carbon nanotube layer after forming a gate structure on the graphene layer or carbon nanotube layer, wherein the gate structure comprises a gate stack, a spacer and a cap layer, the cap layer is located on the gate stack, and the spacer surrounds the gate stack and the cap layer; epitaxially growing a semiconductor layer on the exposed graphene layer or carbon nanotube layer; and forming a metal contact layer on the semiconductor layer. In the present invention, the semiconductor layer is formed on the graphene layer or carbon nanotube layer, and then the metal contact layer is formed on the semiconductor layer, instead of forming the metal contact layer directly from the graphene layer or carbon nanotube layer.

Abstract: Some embodiments include memory cells which have channel-supporting material, dielectric material over the channel-supporting material, carrier-trapping material over the dielectric material and an electrically conductive electrode material over and directly against the carrier-trapping material; where the carrier-trapping material includes gallium, indium, zinc and oxygen. Some embodiments include methods of storing information. A memory cell to is provided which has a channel-supporting material, a dielectric material over the channel-supporting material, a carrier-trapping material over the dielectric material, and an electrically conductive electrode material over and directly against the carrier-trapping material; where the carrier-trapping material includes gallium, indium, zinc and oxygen. It is determined if carriers are trapped in the carrier-trapping material to thereby ascertain a memory state of the memory cell.

Abstract: A method for manufacturing a sloped structure is disclosed. The method includes the steps of: (a) forming a sacrificial film above a substrate; (b) forming a first film above the sacrificial film; (c) forming a second film having a first portion connected to the substrate, a second portion connected to the first film, and a third portion positioned between the first portion and the second portion; (d) removing the sacrificial film; and (e) bending the third portion of the second film after the step (d), thereby sloping the first film with respect to the substrate.

Abstract: Provided are semiconductor devices and methods of fabricating the same. The device may include lower interconnection lines, upper interconnection lines crossing the lower interconnection lines, selection elements disposed at intersections, respectively, of the lower and upper interconnection lines, and memory elements interposed between the selection elements and the upper interconnection lines, respectively. Each of the selection elements may be realized using a semiconductor pattern having a first sidewall, in which a first lower width is smaller than a first upper width, and a second sidewall, in which a second lower width is greater than a second upper width, the first and second sidewalls crossing each other.

Abstract: An integrated circuit structure includes a fin field-effect transistor (FinFET) including a semiconductor fin over and adjacent to insulation regions; and a source/drain region over the insulation regions. The source/drain region includes a first and a second semiconductor region. The first semiconductor region includes silicon and an element selected from the group consisting of germanium and carbon, wherein the element has a first atomic percentage in the first semiconductor region. The first semiconductor region has an up-slant facet and a down-slant facet. The second semiconductor region includes silicon and the element. The element has a second atomic percentage lower than the first atomic percentage. The second semiconductor region has a first portion on the up-slant facet and has a first thickness. A second portion of the second semiconductor region, if any, on the down-slant facet has a second thickness smaller than the first thickness.

Abstract: A method and an electronic device structure comprising at least one access lead to adapted to be connected to an electrical circuit; at least one substrate region; at least one semiconductor die positioned on the substrate; the at least one semiconductor die being operatively connected to the at least one access lead; a dielectric region extending below the at least one semiconductor die; the dielectric region being formed by creating a cavity in the at least one substrate region; whereby the dielectric region operates to reduce electric field stresses produced by the at least one semiconductor die to thereby reduce the possibility of material failure and voltage breakdown.

Abstract: An optoelectronic device is disclosed. The optoelectronic device comprises an active layer and a conducting network layer which comprises a plurality of interconnected metal nanowires and a layer of transparent conducting material in electrical contact with the active layer. The conducting network layer of interconnected metal nanowires is disposed on the layer of transparent conducting material. Above the active layer, light passes through the transparent conducting material to reach the active layer. Each of the nanowires has an elongate, non-spherical configuration and aggregate nanowire length oriented to extend laterally through a plane of the conducting network layer. This provides lengthwise contact of the nanowires to the transparent conducting material.

Abstract: A gain-clamped semiconductor optical amplifier comprises: at least one first surface; at least one second surface, each second surface facing and electrically isolated from a respective first surface; a plurality of nanowires connecting each opposing pair of the first and second surfaces in a bridging configuration; and a signal waveguide overlapping the nanowires such that an optical signal traveling along the signal waveguide is amplified by energy provided by electrical excitation of the nanowires.

Abstract: Embodiments of the invention include a III-nitride semiconductor layer including a first portion having a first defect density and a second portion having a second defect density. The first defect density is greater than the second defect density. An insulating material is disposed over the first portion. The insulating material is not formed on or is removed from the second portion.

Abstract: Methods of forming semiconductor structures include transferring a portion (116a) of a donor structure to a processed semiconductor structure (102) that includes at least one non-planar surface. An amorphous film (144) may be formed over at least one non-planar surface of the bonded semiconductor structure, and the amorphous film may be planarized to form one or more planarized surfaces. Semiconductor structures include a bonded semiconductor structure having at least one non-planar surface, and an amorphous film disposed over the at least one non-planar surface. The bonded semiconductor structure may include a processed semiconductor structure and a portion of a single crystal donor structure attached to a non-planar surface of the processed semiconductor structure.

Abstract: Mechanisms for identifying orientation of a sawed die are provided. By making metal pattern in the corner stress relief region in one corner of the die different from the other corners, users can easily identify the orientation of the die.

Abstract: A semiconductor device and a method of fabricating a semiconductor device are disclosed. Embodiments of the invention use a photosensitive self-assembled monolayer to pattern the surface of a substrate into hydrophilic and hydrophobic regions, and an aqueous (or alcohol) solution of a dopant compound is deposited on the substrate surface. The dopant compound only adheres on the hydrophilic regions. After deposition, the substrate is coated with a very thin layer of oxide to cap the compounds, and the substrate is annealed at high temperatures to diffuse the dopant atoms into the silicon and to activate the dopant. In one embodiment, the method comprises providing a semiconductor substrate including an oxide surface, patterning said surface into hydrophobic and hydrophilic regions, depositing a compound including a dopant on the substrate, wherein the dopant adheres to the hydrophilic region, and diffusing the dopant into the oxide surface of the substrate.

Abstract: A method of forming features on a target layer. The features have a critical dimension that is triple- or quadruple-reduced compared to the critical dimension of portions of a resist layer used as a mask. An intermediate layer is deposited over a target layer and the resist layer is formed over the intermediate layer. After patterning the resist layer, first spacers are formed on sidewalls of remaining portions of the resist layer, masking portions of the intermediate layer. Second spacers are formed on sidewalls of the portions of the intermediate layer. After removing the portions of the intermediate layer, the second spacers are used as a mask to form the features on the target layer. Integrated circuit devices are also disclosed.

Abstract: A microelectronic structure and a method for fabricating the microelectronic structure provide a plurality of voids interposed between a plurality of conductor layers. The plurality of voids is also located between a liner layer and an inter-level dielectric layer. The voids provide for enhanced electrical performance of the microelectronic structure.

Abstract: A semiconductor device includes an insulation layer including a cell contact hole, and a switching device in the cell contact hole, at least a part of a top surface of the switching device being inclined with respect to an axial direction of the cell contact hole.

Abstract: A semiconductor device which is designed based on RDR, suppresses the occurrence of a trouble at the boundary between an active region and a power wire and therearound and is small in size and highly integrated. The semiconductor device includes a first conductive impurity region for functional elements which is formed over the main surface of a semiconductor substrate and a second conductive impurity region for power potential to which power potential is applied in at least one standard cell. It also includes insulating layers which are formed over the main surface of the semiconductor substrate and have throughholes reaching the main surface of the semiconductor substrate, and a conductive layer for contact formed in the throughholes of the insulating layers.

Abstract: A method for formation of a fin field effect transistor (FinFET) device includes forming a mandrel mask on a metal hardmask layer of a film stack, the film stack including a silicon on insulator (SOI) layer located underneath the metal hardmask layer; forming a large feature (FX) mask on the metal hardmask layer; etching the mandrel mask and the FX mask simultaneously into the metal hardmask layer; etching the mandrel mask and the FX mask into the SOI layer using the etched metal hardmask layer as a mask.

Abstract: The present invention related to a method for manufacturing a semiconductor, comprising steps of: providing a growing substrate; forming on the growing substrate to have plural grooves; forming a semiconductor element layer on the growing substrate; and changing the temperature of the growing substrate and the semiconductor element layer so as to separate the semiconductor element layer from the growing substrate.

Abstract: A method for formation of a fin field effect transistor (FinFET) device includes forming a mandrel mask and a large feature (FX) mask on a metal hardmask layer of a film stack, the film stack including a silicon on insulator (SOI) layer located underneath the metal hardmask layer; etching the mandrel mask and the FX mask simultaneously into the metal hardmask layer; and etching the mandrel mask and the FX mask into the SOI layer using the etched metal hardmask layer as a mask.

Abstract: Methods of forming semiconductor structures that include bodies of a semiconductor material disposed between rails of a dielectric material are disclosed. Such methods may include filling a plurality of trenches in a substrate with a dielectric material and removing portions of the substrate between the dielectric material to form a plurality of openings. In some embodiments, portions of the substrate may be undercut to form a continuous void underlying the bodies and the continuous void may be filled with a conductive material. In other embodiments, portions of the substrate exposed within the openings may be converted to a silicide material to form a conductive material under the bodies. For example, the conductive material may be used as a conductive line to electrically interconnect memory device components. Semiconductor structures and devices formed by such methods are also disclosed.

Abstract: A semiconductor device with a high voltage compensation component is manufactured by etching a trench into an epitaxial semiconductor material doped with n-type dopant atoms and p-type dopant atoms and disposing a first semiconductor or insulating material along one or more sidewalls of the trench. The first semiconductor or insulating material has a dopant diffusion constant which is at least 2× different for the n-type dopant atoms than the p-type dopant atoms. A second semiconductor material is disposed in the trench along the first semiconductor or insulating material. The second semiconductor material has a different dopant diffusion constant than the first semiconductor or insulating material.

Abstract: A method of making an electronic device comprising a double bank well-defining structure, which method comprises: providing an electronic substrate; depositing a first insulating material on the substrate to form a first insulating layer; depositing a second insulating material on the first insulating layer to form a second insulating layer; removing a portion of the second insulating layer to expose a portion of the first insulating layer and form a second well-defining bank; depositing a resist on the second insulating layer and on a portion of the exposed first insulating layer; removing the portion of the first insulating layer not covered by the resist, to expose a portion of the electronic substrate and form a first well-defining bank within the second well-defining bank; and removing the resist. The method can provide devices with reduced leakage currents.

Abstract: An actinic ray-sensitive or radiation-sensitive resin composition of the present invention contains a resin (P) which includes a repeating unit (A) having an ionic structural moiety which generates an acid anion by being decomposed due to irradiation with actinic rays or radiation, a repeating unit (B) having a proton acceptor moiety, and a repeating unit (C) having a group which generates an alkali soluble group by being decomposed by the action of an acid, and the resin (P) has at least one repeating unit which is represented by the general formulae (I) to (III) below as the repeating unit (A) (the reference numerals in the general formulae represent the meaning of the description in the scope of the claims and the specifications).

Abstract: A graphene-on-substrate includes a substrate, a first intermediate layer disposed on the substrate, and graphene disposed on the first intermediate layer, where the first intermediate layer comprises a material having an intermediate polarity value between a polarity of the substrate and a polarity of the graphene.

Abstract: 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.

Abstract: Multi-Project Wafers includes a plurality of chiplets from different IP owners. Non-relevant chiplets are implemented with IP protection to inhibit IP disclosure of non-relevant IP owners.

Abstract: A graphene layer is formed on a crystallographic surface having a non-hexagonal symmetry. The crystallographic surface can be a surface of a single crystalline semiconductor carbide layer. The non-hexagonal symmetry surface of the single crystalline semiconductor carbide layer is annealed at an elevated temperature in ultra-high vacuum environment to form the graphene layer. During the anneal, the semiconductor atoms on the non-hexagonal surface of the single crystalline semiconductor carbide layer are evaporated selective to the carbon atoms. As the semiconductor atoms are selectively removed, the carbon concentration on the surface of the semiconductor-carbon alloy layer increases. Despite the non-hexagonal symmetry of the surface of the semiconductor-carbon alloy layer, the remaining carbon atoms can coalesce to form a graphene layer having hexagonal symmetry.

Abstract: Process for manufacturing a semiconductor power device, wherein a trench is formed in a semiconductor body having a first conductivity type; the trench is annealed for shaping purpose; and the trench is filled with semiconductor material via epitaxial growth so as to obtain a first column having a second conductivity type. The epitaxial growth is performed by supplying a gas containing silicon and a gas containing dopant ions of the second conductivity type in presence of a halogenide gas and occurs with uniform distribution of the dopant ions. The flow of the gas containing dopant ions is varied according to a linear ramp during the epitaxial growth; in particular, in the case of selective growth of the semiconductor material in the presence of a hard mask, the flow decreases; in the case of non-selective growth, in the absence of hard mask, the flow increases.

Abstract: A substrate with a vent for a semiconductor device where the vent is integrated within the substrate itself. The integrated air vent forms a passageway or relief path for gas or air within a mold cavity to escape during a transfer molding packaging process. The vents integrated in the substrate reduce trapped gas and mold voids and limit vent flash to improve yield.

Abstract: Semiconductor devices having an optical transceiver include a cladding on a substrate, a protrusion vertically extending trough the cladding and materially in continuity with the substrate, and a coupler on the cladding and the protrusion.

Abstract: In accordance with an embodiment, a semiconductor device includes a substrate, a first insulating film on the substrate, wiring lines including a metal in trenches in the first insulating film, and a second insulating film. The second insulating film covers the first insulating film and the wiring line. The trenches are arranged parallel to one another at predetermined intervals. The dielectric constant of the material of the second insulating film is higher than that of the first insulating film. The lower surface of the second insulating film in a region between the wiring lines locates above a surface that connects the peripheral edges of the upper surfaces of the wiring lines.

Abstract: The invention provides a material for forming a passivation film for a semiconductor substrate. The material includes a polymer compound having an anionic group or a cationic group.

Abstract: A power semiconductor device includes an active device region disposed in a semiconductor substrate, an edge termination region disposed in the semiconductor substrate between the active device region and a lateral edge of the semiconductor substrate and a trench disposed in the edge termination region which extends from a first surface of the semiconductor substrate toward a second opposing surface of the semiconductor substrate. The trench has an inner sidewall, an outer sidewall and a bottom. The inner sidewall is spaced further from the lateral edge of the semiconductor substrate than the outer sidewall, and an upper portion of the outer sidewall is doped opposite as the inner sidewall and bottom of the trench to increase the blocking voltage capacity. Other structures can be provided which yield a high blocking voltage capacity such as a second trench or a region of chalcogen dopant atoms disposed in the edge termination region.

Abstract: A semiconductor wafer (100) having a regular pattern of predetermined separation lanes (102) is provided, wherein the predetermined separation lanes (102) are configured in such a way that the semiconductor wafer is singularizable along the regular pattern.

Abstract: An object of the present invention is to provide an epitaxial wafer on which dislocation is preventable even when a LSA treatment is performed in device processes. An epitaxial wafer according to the present invention includes a wafer 11 whose nitrogen concentration is 1×1012 atoms/cm3 or more or whose specific resistance is 20 m?·cm or less by boron doping, and an epitaxial layer 12 provided on the wafer 11. On the wafer 11, if a thermal treatment is performed at 750° C. for 4 hours and then at 1,000° C. for 4 hours, polyhedron oxygen precipitates grow predominantly over plate-like oxygen precipitates. Therefore, in the device processes, plate-like oxygen precipitates cannot be easily formed. As a result, even when the LSA treatment is performed after various thermal histories in the device processes, it is possible to prevent the dislocation, which is triggered by oxygen precipitates, from generating.

Abstract: A method for forming a silicon film may be performed using a microheater including a substrate and a metal pattern spaced apart from the substrate. The silicon film may be formed on the metal pattern by applying a voltage to the metal pattern of the microheater to heat the metal pattern and by exposing the microheater to a source gas containing silicon. The silicon film may be made of polycrystalline silicon. A method for forming a pn junction may be performed using a microheater including a substrate, a conductive layer on the substrate, and a metal pattern spaced apart from the substrate. The pn junction may be formed between the metal pattern and the conductive layer by applying a voltage to the metal pattern of the microheater to heat the metal pattern. The pn junction may be made of polycrystalline silicon.

Abstract: Provided is a semiconductor device comprising: a PW layer formed at a surface of a semiconductor substrate; an NW layer formed at the surface of the semiconductor substrate to be in contact with the PW layer; a p+ base layer formed at the surface of the semiconductor substrate in the PW layer; an n+ collector layer formed at the surface of the semiconductor substrate in the NW layer; an n+ emitter layer located between the p+ base layer and the n+ collector layer and formed at the surface of the semiconductor substrate in the PW layer; and an n± layer formed between the n+ collector layer and the PW layer to be in contact with the n+ collector layer.

Abstract: A semiconductor chip includes a semiconductor body with a semiconductor layer sequence. An active region intended for generating radiation is arranged between an n-conductive multilayer structure and a p-conductive semiconductor layer. A doping profile is formed in the n-conductive multilayer structure which includes at least one doping peak.

Abstract: A MOSFET includes a silicon carbide substrate, a buffer layer made of silicon carbide formed on the silicon carbide substrate, a drift layer made of silicon carbide of an n conductivity type formed on the buffer layer, a p type body region of a p conductivity type formed in the drift layer to include a main surface of the drift layer opposite to the buffer layer, a source contact electrode formed on the p type body region, and a drain electrode formed on a main surface of the silicon carbide substrate opposite to the buffer layer. A current path region having an impurity concentration higher than that of another region in the drift layer is formed in a region in the drift layer sandwiched between the buffer layer and the body region.

Abstract: In a silicon wafer which has a surface with a plurality of terraces formed stepwise by single-atomic-layer steps, respectively, no slip line is formed.

Abstract: Various embodiments provide a device having a multi-scale superoleophobic surface and methods for forming and using the device, wherein a particulate composite layer including metal-containing particulates is formed on a textured micron-/sub-micron surface of a semiconductor layer to provide device with multi-scale rough surface.

Abstract: There is provided an SOS substrate with reduced stress. The SOS substrate is a silicon-on-sapphire (SOS) substrate comprising a sapphire substrate and a monocrystalline silicon film on or above the sapphire substrate. The stress of the silicon film of the SOS substrate as measured by a Raman shift method is 2.5×108 Pa or less across an entire in-plane area of the SOS substrate.

Abstract: A semiconductor device includes a drift layer having a first conductivity type, a well region in the drift layer having a second conductivity type opposite the first conductivity type, and a source region in the well region, The source region has the first conductivity type and defines a channel region in the well region. The source region includes a lateral source region adjacent the channel region and a plurality of source contact regions extending away from the lateral source region opposite the channel region. A body contact region having the second conductivity type is between at least two of the plurality of source contact regions and is in contact with the well region. A source ohmic contact overlaps at least one of the source contact regions and the body contact region. A minimum dimension of a source contact area of the semiconductor device is defined by an area of overlap between the source ohmic contact and the at least one source contact region.

Abstract: A semiconductor device and a method of fabricating a semiconductor device are disclosed. Embodiments of the invention use a photosensitive self-assembled monolayer to pattern the surface of a substrate into hydrophilic and hydrophobic regions, and an aqueous (or alcohol) solution of a dopant compound is deposited on the substrate surface. The dopant compound only adheres on the hydrophilic regions. After deposition, the substrate is coated with a very thin layer of oxide to cap the compounds, and the substrate is annealed at high temperatures to diffuse the dopant atoms into the silicon and to activate the dopant. In one embodiment, the method comprises providing a semiconductor substrate including an oxide surface, patterning said surface into hydrophobic and hydrophilic regions, depositing a compound including a dopant on the substrate, wherein the dopant adheres to the hydrophilic region, and diffusing the dopant into the oxide surface of the substrate.

Abstract: In one embodiment, a method of forming a plug includes providing a base layer, providing an intermediate oxide layer above an upper surface of the base layer, providing an upper layer above an upper surface of the intermediate oxide layer, etching a trench including a first trench portion extending through the upper layer, a second trench portion extending through the oxide layer, and a third trench portion extending into the base layer, depositing a first material portion within the third trench portion, depositing a second material portion within the second trench portion, and depositing a third material portion within the first trench portion.

Abstract: Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure.