Abstract: A method for growing a semi-polar nitride semiconductor thin film via metalorganic chemical vapor deposition (MOCVD) on a substrate, wherein a nitride nucleation or buffer layer is grown on the substrate prior to the growth of the semi-polar nitride semiconductor thin film.

Abstract: A semiconductor device capable of high speed operation is provided. Further, a highly reliable semiconductor device is provided. An oxide semiconductor having crystallinity is used for a semiconductor layer of a transistor. A channel formation region, a source region, and a drain region are formed in the semiconductor layer. The source region and the drain region are formed in such a manner that one or more of elements selected from rare gases and hydrogen are added to the semiconductor layer by an ion doping method or an ion implantation method with the use of a channel protective layer as a mask.

Abstract: A semiconductor device in which fluctuation in electric characteristics due to miniaturization is less likely to be caused is provided. The semiconductor device includes an oxide semiconductor film including a first region, a pair of second regions in contact with side surfaces of the first region, and a pair of third regions in contact with side surfaces of the pair of second regions; a gate insulating film provided over the oxide semiconductor film; and a first electrode that is over the gate insulating film and overlaps with the first region. The first region is a CAAC oxide semiconductor region. The pair of second regions and the pair of third regions are each an amorphous oxide semiconductor region containing a dopant. The dopant concentration of the pair of third regions is higher than the dopant concentration of the pair of second regions.

Abstract: A miniaturized semiconductor device including a transistor in which a channel formation region is formed using an oxide semiconductor film and variation in electric characteristics due to a short-channel effect is suppressed is provided. In addition, a semiconductor device whose on-state current is improved is provided. A semiconductor device is provided with an oxide semiconductor film including a pair of second oxide semiconductor regions which are amorphous regions and a first oxide semiconductor region located between the pair of second oxide semiconductor regions, a gate insulating film, and a gate electrode provided over the first oxide semiconductor region with the gate insulating film interposed therebetween. Hydrogen or a rare gas is added to the second oxide semiconductor regions.

Abstract: Radiation detector. The detector includes an ionic junction having an ionically bonded wide band gap material having a first region dominated by positively charged ionic defects in intimate contact with a second region dominated by negatively charged ionic defects forming depleted regions on both sides of the junction resulting in a built-in electric field. The detector also includes an ionic junction having a first ionically bonded wide band gap material dominated by positively charged ionic defects in intimate contact with a second ionically bonded wide band gap material dominated by negatively charged ionic defects forming depleted regions on both sides of the junction resulting in a built-in electric field. Circuit means are provided to establish a voltage across the junction so that radiation impinging upon the junction will cause a current to flow in the circuit.

Abstract: An object is to provide a semiconductor memory device capable of shortening writing operation by concurrently determining potentials of memory cells on one word line. A plurality of transistors having switching characteristics are connected to one potential control circuit, whereby writing potentials are determined concurrently. A potential continues to be changed (raised or decreased) stepwise, a desired potential is determined while changing the potential, and whether data resulted from reading with respect to written data is correct or not is continuously checked, so that high-precision writing operation and high-precision reading operation can be achieved. In addition, favorable switching characteristics and holding characteristics of a transistor including an oxide semiconductor are utilized.

Abstract: The graphene substrate may include a metal oxide film on a substrate, and a graphene layer on the metal oxide film. The concentration of oxygen in the metal oxide film may be gradually reduced from the substrate towards the graphene layer, and the graphene layer may be formed directly on the metal oxide film.

Abstract: A photo sensing unit used in a photo sensor includes a photo sensing transistor, a storage capacitor, and a switching transistor. The photo sensing transistor receives a light signal for inducing a photo current correspondingly, and a source and a gate thereof are respectively coupled to the first signal source and the second signal source. The storage capacitor stores electrical charges induced by the light signal, one terminal thereof is coupled to drain of the photo sensing transistor, and another terminal thereof is coupled to a low voltage. The switching transistor is controlled by the second signal source for outputting a readout signal from the storage capacitor to the signal readout line. The threshold voltage of the photo transistor is higher than that of the switching transistor.

Abstract: A thin film transistor array panel is provided that includes: a gate electrode that is disposed on an insulating substrate; a gate insulating layer that is disposed on the gate electrode; an oxide semiconductor that is disposed on the gate insulating layer; a blocking layer that is disposed on the oxide semiconductor; a source electrode and a drain electrode that are disposed on the blocking layer; a passivation layer that is disposed on the source electrode and drain electrode; and a pixel electrode that is disposed on the passivation layer. The blocking layer includes a first portion that is covered by the source electrode and drain electrode and a second portion that is not covered by the source electrode and drain electrode, and the first portion and the second portion include different materials.

Abstract: An oxide semiconductor film which has more stable electric conductivity is provided. Further, a semiconductor device which has stable electric characteristics and high reliability is provided by using the oxide semiconductor film. An oxide semiconductor film includes a crystalline region, and the crystalline region includes a crystal in which an a-b plane is substantially parallel with a surface of the film and a c-axis is substantially perpendicular to the surface of the film; the oxide semiconductor film has stable electric conductivity and is more electrically stable with respect to irradiation with visible light, ultraviolet light, and the like. By using such an oxide semiconductor film for a transistor, a highly reliable semiconductor device having stable electric characteristics can be provided.

Abstract: This invention describes a semiconductor material of general formula (I) Me12Me21-xMe3xMe4(C11-yC2y)4, in which x stands for a numeric value from 0 to 1, and y stands for a numeric value of 0 to 1, as well as its use as an absorber material in a solar cell. The metal Mel is a metal which is selected from the metals in group 11 of the periodic table of the elements (Cu, Ag or Au). The metals Me2 and Me3 are selected from the elements of the 12th group of the periodic table of elements (Zn, Cd & Hg). The metal Me4 is a metal which is selected from the 4th main group of the periodic table of elements (C, Si, Ge, Sn and Pb). The non-metals C1 and C2 are selected from the group of chalcogenides (S, Se and Te).

Abstract: An electrical circuit component includes a first electrode, a plurality of second electrodes and a negative differential resistance (NDR) material. The first electrode and the plurality of second electrodes are connected to the NDR material and the NDR material is to electrically connect the first electrode to one of the plurality of second electrodes when a sufficient voltage is applied between the first electrode and the one of the plurality of second electrodes through the NDR material.

Abstract: A MOSFET cell of a semiconductor device includes a polysilicon gate electrode and an n+-source region formed in an upper portion of an n?-drift layer. An interlayer insulating film covers the gate electrode. An Al source electrode extends on the interlayer insulating film. An Al gate pad is connected to the gate electrode. A barrier metal layer that prevents diffusion of aluminum is interposed between the source electrode and the interlayer insulating film, and between the gate pad and the gate electrode.

Abstract: A method of producing particles containing metal oxide for use in semiconductor devices may include heating metal-containing particles in a flame produced by a mixture of oxygen and a fuel component comprising at least one combustible gas selected from hydrogen and hydrocarbons. The oxygen may be present in the mixture in a proportion of not less than 10 mole % below, and not more than 60 mole % above, a stoichiometric amount relative to the fuel component, so as to oxidize metal in at least an outer shell of the particles. The method may include cooling the oxidized particles by feeding them into a liquid, collecting the cooled oxidized particles; and providing a distance between entry of the particles into the flame and collection of the particles of at least 300 mm.

Abstract: Method of producing a semiconductor device, comprising: a) providing a semiconductor substrate, b) making a first amorphous layer in a top layer of the semiconductor substrate by a suitable implant, the first amorphous layer having a first depth, c) implanting a first dopant into the semiconductor substrate to provide the first amorphous layer with a first doping profile, d) applying a first solid phase epitaxial regrowth action to partially regrow the first amorphous layer and form a second amorphous layer having a second depth that is less than the first depth and activate the first dopant, e) implanting a second dopant into the semiconductor substrate to provide the second amorphous layer with a second doping profile with a higher doping concentration than the first doping profile, f) applying a second solid phase epitaxial regrowth action to regrow the second amorphous layer and activate the second dopant.

Abstract: The invention provides a STI structure and method for forming the same. The STI structure includes a semiconductor substrate; a first trench embedded in the semiconductor substrate and filled up with a first dielectric layer; and a second trench formed on a top surface of the semiconductor substrate and interconnected with the first trench, wherein the second trench is filled up with a second dielectric layer, a top surface of the second dielectric layer is flushed with that of the semiconductor substrate, and the second trench has a width smaller than that of the first trench. The invention reduces dimension of divots and improves performance of the semiconductor device.

Abstract: Disclosed are a GaN-based compound power semiconductor device and a manufacturing method thereof, in which on a GaN power semiconductor element, a contact pad is formed for flip-chip bonding, and a bonding pad of a module substrate to be mounted with the GaN power semiconductor element is formed with a bump so as to modularize an individual semiconductor element. In the disclosed GaN-based compound power semiconductor device, an AlGaN HEMT element is flip-chip bonded to the substrate, so that heat generated from the element can be efficiently radiated.

Abstract: A novel interconnection structure which is excellent in adhesion and is capable of realizing low resistance and low contact resistance is provided. An interconnection structure including an interconnection film and a semiconductor layer of a thin film transistor above a substrate in this order from the side of a substrate, wherein the semiconductor layer is composed of an oxide semiconductor, is provided.

Abstract: The invention provides a STI structure and a method for manufacturing the same. The STI includes a semiconductor substrate; a first trench formed on the upper surface of the semiconductor substrate and filled with an epitaxial layer, wherein the upper surface of the epitaxial layer is higher than that of the semiconductor substrate; and a second trench formed on the epitaxial layer and filled with a first dielectric layer, wherein the upper surface of the first dielectric layer is flush with that of the epitaxial layer, and the width of the second trench is smaller than that of the first trench. The invention reduces the influences of divots on performance of the semiconductor device.

Abstract: An object is to provide a semiconductor memory device which can be miniaturized and also secures a sufficient margin for the refresh period. A memory cell includes a reading transistor, a writing transistor, and a capacitor. In the above structure, the capacitor controls a potential applied to a gate of the reading transistor. The writing transistor controls writing and erasing of data and, when the transistor is off, has small current so that loss of electric charges stored in the capacitor, which is due to leakage current of the writing transistor, can be prevented. A semiconductor layer included in the writing transistor is provided so as to extend from the gate electrode toward a source region of the reading transistor. The capacitor is provided to overlap with the gate electrode of the reading transistor.

Abstract: A vertical type GaN series field effect transistor having excellent pinch-off characteristics is provided. A compound semiconductor device includes a conductive semiconductor substrate, a drain electrode formed on a bottom surface of the conductive semiconductor substrate, a current blocking layer formed on a top surface of the conductive semiconductor substrate, made of high resistance compound semiconductor or insulator, and having openings, an active layer of compound semiconductor burying the openings and extending on an upper surface of the current blocking layer, a gate electrode formed above the openings and above the active layer, and a source electrode formed laterally spaced from the gate electrode and formed above the active layer.

Abstract: A method for manufacturing a bonded wafer having a semiconductor film on a handle substrate involving the steps of: implanting ions into a semiconductor substrate to form an ion-implanted layer; subjecting the surface of at least one of the semiconductor substrate and the handle substrate to a surface activation treatment; bonding the surface of the semiconductor substrate to the surface of the handle substrate at a temperature from 50° C. to 350° C.; heating the bonded substrates at a maximum temperature from 200° C. to 350° C. to obtain a bonded body; and transferring a semiconductor film to the handle substrate by subjecting the bonded body to a temperature 30° C. to 100° C. higher than the bonding temperature, and irradiating the bonded body with visible light from a handle or semiconductor substrate side toward the ion-implanted layer of the semiconductor substrate to embrittle the interface of the ion-implanted layer.

Abstract: InP epitaxial material is directly bonded onto a Silicon-On-Insulator (SOI) wafer having Vertical Outgassing Channels (VOCs) between the bonding surface and the insulator (buried oxide, or BOX) layer. H2O and other molecules near the bonding surface migrate to the closest VOC and are quenched in the buried oxide (BOX) layer quickly by combining with bridging oxygen ions and forming pairs of stable nonbridging hydroxyl groups (Si—OH). Various sizes and spacings of channels are envisioned for various devices.

Abstract: An oxide semiconductor thin film transistor includes a gate electrode on a substrate, the gate electrode having a first area, a gate insulation layer on the gate electrode, the gate insulation layer covering the gate electrode, an active layer on the gate insulation layer, the active layer having a second area that is smaller than the first area, a source electrode on the active layer, the source electrode contacting a source region of the active layer, a drain electrode on the active layer, the drain electrode contacting a drain region of the active layer, and a passivation layer covering the active layer, the source electrode, and the drain electrode.

Abstract: A diode and memory device including the diode, where the diode includes a conductive portion and another portion formed of a first material that has characteristics allowing a first decrease in a resistivity of the material upon application of a voltage to the material, thereby allowing current to flow there through, and has further characteristics allowing a second decrease in the resistivity of the first material in response to an increase in temperature of the first material.

Abstract: A method of implementing bandgap tuning of a graphene-based switching device includes subjecting a bi-layer graphene to an electric field while simultaneously subjecting the bi-layer graphene to an applied strain that reduces an interlayer spacing between the bi-layer graphene, thereby creating a bandgap in the bi-layer graphene.

Abstract: An oxide semiconductor including: (A) at least one element of zinc (Zn) and tin (Sn); and (B) at least one element of arsenic (As), antimony (Sb), chromium (Cr), cerium (Ce), tantalum (Ta), neodymium (Nd), niobium (Nb), scandium (Sc), yttrium (Y), and hafnium (Hf), is provided.

Abstract: A metal oxide semiconductor device including an active layer of metal oxide, a layer of gate dielectric, and a layer of low trap density material. The layer of low trap density material is sandwiched between the active layer of metal oxide and the layer of gate dielectric. The layer of low trap density material has a major surface parallel and in contact with a major surface of the active layer of metal oxide to form a low trap density interface with the active layer of metal oxide. A second layer of low trap density material can optionally be placed in contact with the opposed major surface of the active layer of metal oxide so that a low trap density interface is formed with both surfaces of the active layer of metal oxide.

Abstract: A semiconductor module having one or more silicon carbide diode elements mounted on a switching element is provided in which the temperature rise is reduced by properly disposing each of the diode elements on the switching element, to thereby provide a thermal dissipation path for the respective diode elements. The respective diode elements are arranged on a non-central portion of the switching element, to facilitate dissipation of the heat produced by each of the diode elements, whereby the temperature rise in the semiconductor module is reduced.

Abstract: A system is provided for the manufacture of carbon based electrical components including, an ultraviolet light source; a substrate receiving unit whereby a substrate bearing a first layer of carbon based semiconductor is received and disposed beneath the ultraviolet light source; a mask disposed between the ultraviolet light source and the carbon based semiconductor layer; a doping agent precursor source; and environmental chemical controls, configured such that light from the ultraviolet light source irradiates a doping agent precursor and the first carbon layer.

Abstract: A nitride-based semiconductor substrate may includes a plurality of hollow member patterns arranged on a substrate, a nitride-based seed layer formed on the substrate between the plurality of hollow member patterns, and a nitride-based buffer layer on the nitride-based seed layer so as to cover the plurality of hollow member patterns, wherein the plurality of hollow member patterns contact the substrate in a first direction and both ends of each of the plurality of hollow member patterns are open in the first direction.

Abstract: An SOI substrate and a manufacturing method of the SOI substrate, by which enlargement of the substrate is possible and its productivity can be increased, are provided. A step (A) of cutting a first single crystal silicon substrate to form a second single crystal silicon substrate which has a chip size; a step (B) of forming an insulating layer on one surface of the second single crystal silicon substrate, and forming an embrittlement layer in the second single crystal substrate; and a step (C) of bonding a substrate having an insulating surface and the second single crystal silicon substrate with the insulating layer therebetween, and conducting heat treatment to separate the second single crystal silicon substrate along the embrittlement layer, and forming a single crystal silicon thin film on the substrate having an insulating surface, are conducted.

Abstract: A device includes an epitaxially grown crystalline material within an area confined by an insulator. A surface of the crystalline material has a reduced roughness. One example includes obtaining a surface with reduced roughness by creating process parameters which result in the dominant growth component of the crystal to be supplied laterally from side walls of the insulator. In a preferred embodiment, the area confined by the insulator is an opening in the insulator having an aspect ratio sufficient to trap defects using an ART technique.

Abstract: A semiconductor device includes an interposer mounting a semiconductor chip.

Abstract: A semiconductor device according to one embodiment includes an element isolation insulating film formed on a substrate, an element region and a dummy pattern region demarcated by the element isolation insulating film on the substrate, a first epitaxial crystal layer formed on the substrate within the element region, and a second epitaxial crystal layer formed on the substrate within the dummy pattern region. The first epitaxial crystal layer is made up of crystals that have a different lattice constant from that of the crystals that constitute the substrate. The second epitaxial crystal layer is made up of the same crystals as the first epitaxial crystal layer. The (111) plane of the substrate that includes any points on the interface between the second epitaxial crystal layer and the substrate is surrounded by the element isolation insulating film in a deeper region than the second epitaxial crystal layer.

Abstract: A method for preparing zinc oxide nanostructures using arc discharge is disclosed. The method comprises the provision of an anode and a cathode in an arc discharge chamber. Current is supplied to the anode and the cathode to establish an arc discharge between the cathode and the anode to vaporise the anode and produce zinc oxide nanostructures. Contemplated is the use of the zinc oxide nanostructures to produce components that have applications in, for example, optoelectronics, energy storage devices, field emission devices, and sensors such as UV photosensors, gas sensors and humidity sensors.

Abstract: Example embodiments disclose transistors, methods of manufacturing the same, and electronic devices including transistors. An active layer of a transistor may include a plurality of material layers (oxide layers) with different energy band gaps. The active layer may include a channel layer and a photo sensing layer. The photo sensing layer may have a single-layered or multi-layered structure. When the photo sensing layer has a multi-layered structure, the photo sensing layer may include a first material layer and a second material layer that are sequentially stacked on a surface of the channel layer. The first layer and the second layer may be alternately stacked one or more times.

Abstract: An object is to provide a method for manufacturing a semiconductor device without exposing a specific layer to moisture or the like at all. A thin film element is manufactured in such a manner that a first film, a second film, and a third film are stacked in this order; a resist mask is formed over the third film; a mask layer is formed by etching the third film with the use of the resist mask; the resist mask is removed; a second layer and a first layer are formed by performing dry etching on the second film and the first film with the use of the mask layer; a fourth film is formed to cover at least the second layer and the first layer; and sidewall layers are formed to cover at least the entire side surfaces of the first layer by performing etch back on the fourth film.

Abstract: A plurality of metal patterns are disposed on a substrate. A support structure is provided between the plurality of metal patterns. The support structure has a supporter and a glue layer. Each of the plurality of metal patterns has a greater vertical length than a horizontal length on the substrate when viewed from a cross-sectional view. The supporter has a band gap energy of at least 4.5eV. The glue layer is in contact with the plurality of metal patterns. The supporter and the glue layer are formed of different materials.

Abstract: The semiconductor of the present invention has iron sulfide and a forbidden band control element contained in the iron sulfide. The forbidden band control element has a property capable of controlling the forbidden band of iron sulfide on the basis of the number density of the forbidden band control element in the iron sulfide. An n-type semiconductor is manufactured by incorporating a group 13 element of the IUPAC system into iron sulfide. Moreover, a p-type semiconductor is manufactured by incorporating a group Ia element into iron sulfide. A semiconductor junction device or a photoelectric converter is manufactured by using the n-type semiconductor and the p-type semiconductor.

Abstract: Provided is a bottom gate type thin film transistor including on a substrate (1) a gate electrode (2), a first insulating film (3) as a gate insulating film, an oxide semiconductor layer (4) as a channel layer, a second insulating film (5) as a protective layer, a source electrode (6), and a drain electrode (7), in which the oxide semiconductor layer (4) includes an oxide including at least one selected from the group consisting of In, Zn, and Sn, and the second insulating film (5) includes an amorphous oxide insulator formed so as to be in contact with the oxide semiconductor layer (4) and contains therein 3.8×1019 molecules/cm3 or more of a desorbed gas observed as oxygen by temperature programmed desorption mass spectrometry.

Abstract: The present invention relates to a crack-free monocrystalline nitride layer having the composition AlxGa1-xN, where 0?x?0.3, and a substrate that is likely to generate tensile stress in the nitride layer. The structure successively includes the substrate; a nucleation layer; a monocrystalline intermediate layer having a selected thickness on the nucleation layer; a monocrystalline seed layer of an AIBN compound in which the boron content is between 0 and 10% having a selected thickness on the intermediate layer and a relaxation rate, at ambient temperature, of less than 80%; and the monocrystalline nitride layer.

Abstract: A semiconductor device includes a substrate, a buffer layer on the substrate, and a plurality of nitride semiconductor layers on the buffer layer. The semiconductor device further includes at least one masking layer and at least one inter layer between the plurality of nitride semiconductor layers. The at least one inter layer is on the at least one masking layer.

Abstract: The graphene device may include an upper oxide layer on at least one embedded gate, and a graphene channel and a plurality of electrodes on the upper oxide layer. The at least one embedded gate may be formed on the substrate. The graphene channel may be formed on the plurality of electrodes, or the plurality of electrodes may be formed on the graphene channel.

Abstract: Provided is a semiconductor wafer including: a base wafer containing silicon; an inhibitor that has been formed on the base wafer, has an aperture in which a surface of the base wafer is exposed, and inhibits crystal growth; and a light-absorptive structure that has been formed inside the aperture in contact with a surface of the base wafer exposed inside the aperture, where the light-absorptive structure includes a first semiconductor and a second semiconductor.

Abstract: A method of manufacturing a semiconductor device, wherein the method comprises applying a first layer comprising silicon to a second layer comprising silicon carbide, wherein an interface is defined between the first and second layers; and oxidising sonic or all of the first layer.

Abstract: A method for fabricating a stackable integrated circuit layer and a device made from the method are disclosed. A stud bump is defined on the contact pad of an integrated circuit die and the stud-bumped die encapsulated in a potting material to define a potted assembly. A predetermined portion of the potting material is removed whereby a portion of the stud bump is exposed. One or more electrically conductive traces are defined on the layer surface and in electrical connection with the stud bump to reroute the integrated circuit contacts to predetermined locations on the layer to provide a stackable neolayer.

Abstract: A semiconductor device according to an embodiment, includes a catalytic metal film, a graphene film, a contact plug, and an adjustment film. The catalytic metal film is formed above a substrate. The graphene film is formed on the catalytic metal film. The contact plug is connected to the graphene film. The adjustment film is formed in a region other than a region connected to the contact plug of a surface of the graphene film to adjust a Dirac point position in a same direction as the region connected to the contact plug with respect to a Fermi level.

Abstract: A memory cell structure and method for forming the same. The method includes forming a pore within a dielectric layer. The pore is formed over the center of an electrically conducting bottom electrode. The method includes depositing a thermally insulating layer along at least one sidewall of the pore. The thermally insulating layer isolates heat from phase change current to the volume of the pore. In one embodiment phase change material is deposited within the pore and the volume of the thermally insulating layer. In another embodiment a pore electrode is formed within the pore and the volume of the thermally insulating layer, with the phase change material being deposited above the pore electrode. The method also includes forming an electrically conducting top electrode above the phase change material.

Abstract: The mechanisms of forming SiC crystalline regions on Si substrate described above enable formation and integration of GaN-based devices and Si-based devices on a same substrate. The SiC crystalline regions are formed by implanting carbon into regions of Si substrate and then annealing the substrate. An implant-stop layer is used to cover the Si device regions during formation of the SiC crystalline regions.