Abstract: A semiconductor substrate includes: single crystal silicon; a mask material formed on a surface of the single crystal silicon and having an opening; a silicon carbide film formed on a portion exposed in the opening of the single crystal silicon; and a single crystal silicon carbide film formed so as to cover the silicon carbide film and the mask material. The mask material has a viscosity of 105 Pa·S or more and 1014.5 Pa·S or less in a temperature range of 950 to 1400° C.

Abstract: A semiconductor device of an embodiment includes: a silicon carbide substrate including first and second principal surfaces; a first conductive-type first silicon carbide layer provided on the first principal surface of the silicon carbide substrate; a second conductive-type first silicon carbide region formed on a surface of the first silicon carbide layer; a first conductive-type second silicon carbide region formed on a surface of the first silicon carbide region; a second conductive-type third silicon carbide region formed on the surface of the first silicon carbide region; a gate insulating film continuously formed on the surfaces of the first silicon carbide layer, the first silicon carbide region, and the second silicon carbide region; a first electrode formed of silicon carbide formed on the gate insulating film; a second electrode formed on the first electrode; an interlayer insulating film for covering the first and second electrodes; a third electrode electrically connected to the second silicon ca

Abstract: There are provided a high-quality semiconductor device having stable characteristics and a method for manufacturing such a semiconductor device. The semiconductor device includes: a substrate having a main surface; and a silicon carbide layer formed on the main surface of the substrate and including a side surface inclined relative to the main surface. The side surface substantially includes a {03-3-8} plane. The side surface includes a channel region.

Abstract: A method includes forming a stressed Si layer in a trench formed in a stress layer deposited on a substrate. The stressed Si layer forms an active channel region of a device. The method further includes forming a gate structure in the active channel region formed from the stressed Si layer.

Abstract: A semiconductor device includes a first conduction type semiconductor substrate, a first conduction type semiconductor deposition layer, a trench, second conduction type wells, a JFET region, a first conduction type first source region, a first source region, a trench-type source electrode, a gate insulator film, a gate electrode, and a drain electrode. The trench is formed substantially perpendicularly to the semiconductor deposition layer so that the semiconductor deposition layer exposes to a bottom of the trench. The second conduction type second source region are formed in the first conduction type first source region. The trench-type source electrode is in contact with the first source region, the second source region, and the first conduction type semiconductor deposition layer to configure a Schottky junction.

Abstract: LED devices and methods for making such devices are provided. One such method may include forming epitaxially a substantially single crystal SiC layer on a substantially single crystal Si wafer, forming epitaxially a substantially single crystal diamond layer on the SiC layer, doping the diamond layer to form a conductive diamond layer, removing the Si wafer to expose the SiC layer opposite to the conductive diamond layer, forming epitaxially a plurality of semiconductor layers on the SiC layer such that at least one of the semiconductive layers contacts the SiC layer, and coupling an n-type electrode to at least one of the semiconductor layers such that the plurality of semiconductor layers is functionally located between the conductive diamond layer and the n-type electrode.

Abstract: A semiconductor rectifying device of an embodiment includes a first-conductive-type semiconductor substrate made of a wide bandgap semiconductor, a first-conductive-type semiconductor layer formed on an upper surface of the semiconductor substrate and made of the wide bandgap semiconductor having an impurity concentration lower than that of the semiconductor substrate, a first-conductive-type first semiconductor region formed at a surface of the semiconductor layer and made of the wide bandgap semiconductor, a second-conductive-type second semiconductor region formed around the first semiconductor region and made of the wide bandgap semiconductor, a second-conductive-type third semiconductor region formed around the first semiconductor region and made of the wide bandgap semiconductor having a junction depth deeper than a junction depth of the second semiconductor region, a first electrode that is formed on the first, second, and third semiconductor regions, and a second electrode formed on a lower surface of

Abstract: The present invention provides novel silicon-germanium hydride compounds, methods for their synthesis, methods for their deposition, and semiconductor structures made using the novel compounds.

Abstract: A method of manufacturing a silicon carbide semiconductor device having a silicon carbide layer, the method including a step of implanting at least one of Al ions, B ions and Ga ions having an implantation concentration in a range not lower than 1E19 cm?3 and not higher than 1E21 cm?3 from a main surface of the silicon carbide layer toward the inside of the silicon carbide layer while maintaining the temperature of the silicon carbide layer at 175° C. or higher, to form a p-type impurity layer; and forming a contact electrode whose back surface establishes ohmic contact with a front surface of the p-type impurity layer on the front surface of the p-type impurity layer.

Abstract: There are provided a semiconductor device of low cost and high quality, a combined substrate used for manufacturing the semiconductor device, and methods for manufacturing them. The method for manufacturing the semiconductor device includes the steps of: preparing a single-crystal semiconductor member; preparing a supporting base; connecting the supporting base and the single-crystal semiconductor member to each other through a connecting layer containing carbon; forming an epitaxial layer on a surface of the single-crystal semiconductor member; forming a semiconductor element using the epitaxial layer; separating the single-crystal semiconductor member from the supporting base by oxidizing and accordingly decomposing the connecting layer after the step of forming the semiconductor element; and dividing the single-crystal semiconductor member separated from the supporting base.

Abstract: An electronic device includes a semiconductor layer, a primary junction in the semiconductor layer, a lightly doped region surrounding the primary junction and a junction termination structure in the lightly doped region adjacent the primary junction. The junction termination structure has an upper boundary, a side boundary, and a corner between the upper boundary and the side boundary, and the lightly doped region extends in a first direction away from the primary junction and normal to a point on the upper boundary by a first distance that is smaller than a second distance by which the lightly doped region extends in a second direction away from the primary junction and normal to a point on the corner. At least one floating guard ring segment may be provided in the semiconductor layer outside the corner of the junction termination structure. Related methods are also disclosed.

Abstract: A switching semiconductor device is provided, in which a negative gate voltage can be applied to the semiconductor device in an OFF state so as to increase a breakdown voltage of the gate junction without impairing a normally-off function of the semiconductor device and the ON-resistance. The switching semiconductor device is fabricated by using a semiconductor substrate with a band gap of 2.0 eV or more. In a JFET structure where a p+ type gate region and an n type source region are in contact so that a negative gate voltage can be applied, the p+ type gate region and an n+ type source region with a high impurity concentration are disposed with interposing an n type source region with an impurity concentration lower than that of the p+ type gate region and higher than that of a drift region of the JFET therebetween.

Abstract: A compound semiconductor device includes: an electron transit layer made of GaN; a channel layer made of AlGaN; a source electrode, a gate electrode and a drain electrode that are provided on the channel layer; a cap layer that is provided at least between the source electrode and the gate electrode and between the gate electrode and the drain electrode and is made of GaN; a recess portion that is provided in the cap layer between the gate electrode and the drain electrode; and a thick portion that is provided in the cap layer between the recess portion and the drain electrode and has a thickness larger than the recess portion.

Abstract: A hermetically sealed integrated circuit package that includes a cavity housing a semiconductor die, whereby the cavity is pressurized during assembly and when formed. The invention prevents the stress on a package created when the package is subject to high temperatures at atmospheric pressure and then cooled from reducing the performance of the die at high voltages. By packaging a die at a high pressure, such as up to 50 PSIG, in an atmosphere with an inert gas, and providing a large pressure in the completed package, the dies are significantly less likely to arc at higher voltages, allowing the realization of single die packages operable up to at least 1200 volts. Moreover, the present invention is configured to employ brazed elements compatible with Silicon Carbide dies which can be processed at higher temperatures.

Abstract: A semiconductor-carbon alloy layer is formed on the surface of a semiconductor substrate, which may be a commercially available semiconductor substrate such as a silicon substrate. The semiconductor-carbon alloy layer is converted into at least one graphene layer during a high temperature anneal, during which the semiconductor material on the surface of the semiconductor-carbon alloy layer is evaporated selective to the carbon atoms. As the semiconductor atoms are selectively removed and the carbon concentration on the surface of the semiconductor-carbon alloy layer increases, the remaining carbon atoms in the top layers of the semiconductor-carbon alloy layer coalesce to form a graphene layer having at least one graphene monolayer. Thus, a graphene layer may be provided on a commercially available semiconductor substrate having a diameter of 200 mm or 300 mm.

Abstract: An electronic device includes a silicon carbide drift region having a first conductivity type, a Schottky contact on the drift region, and a plurality of junction barrier Schottky (JBS) regions at a surface of the drift region adjacent the Schottky contact. The JBS regions have a second conductivity type opposite the first conductivity type and have a first spacing between adjacent ones of the JBS regions. The device further includes a plurality of surge protection subregions having the second conductivity type. Each of the surge protection subregions has a second spacing between adjacent ones of the surge protection subregions that is less than the first spacing.

Abstract: The present application provides a semiconductor structure and a method for manufacturing the same. The semiconductor structure comprises a semiconductor substrate, a semiconductor fin located on the semiconductor substrate, and an etch stop layer located between the semiconductor substrate and the semiconductor fin, wherein a lateral sidewall of the semiconductor fin is substantially on the Si {111} crystal plane. Since the semiconductor fin exhibits better surface quality and less crystal defects, it is favorable for manufacturing FINFET.

Abstract: A silicon carbide semiconductor device includes a silicon carbide semiconductor substrate and a trench. The silicon carbide semiconductor substrate has an offset angle with respect to a (0001) plane or a (000-1) plane and has an offset direction in a <11-20> direction. The trench is provided from a surface of the silicon carbide semiconductor substrate. The trench extends in a direction whose interior angle with respect to the offset direction is 30 degrees or ?30 degrees.

Abstract: Provided is an organopolysiloxane composition that provides a cured product which has excellent heat resistance and does not peel or crack even under high temperatures. The organopolysiloxane composition comprises (A) an organopolysiloxane having difunctional siloxane units (D units) and trifunctional siloxane units (T units), and a weight-average molecular weight of 37,000 to 140,000 in which the molar ratio (T/D) of the T units to the D units is 0.3 to 0.8; and (B) an organopolysiloxane having the difunctional siloxane units (D units) and the trifunctional siloxane units (T units), and a weight-average molecular weight of 1,000 to 60,000 in which the molar ratio (T/D) of the T units to the D units is 0.15 or less, the organopolysiloxane composition being characterized by having a molar ratio (B/A) of the organopolysiloxane (B) to the organopolysiloxane (A) of 1.5 to 6.5.

Abstract: A silicon carbide semiconductor device (90), includes: 1) a silicon carbide substrate (1); 2) a gate electrode (7) made of polycrystalline silicon; and 3) an ONO insulating film (9) sandwiched between the silicon carbide substrate (1) and the gate electrode (7) to thereby form a gate structure, the ONO insulating film (9) including the followings formed sequentially from the silicon carbide substrate (1): a) a first oxide silicon film (O) (10), b) an SiN film (N) (11), and c) an SiN thermally-oxidized film (O) (12, 12a, 12b). Nitrogen is included in at least one of the following places: i) in the first oxide silicon film (O) (10) and in a vicinity of the silicon carbide substrate (1), and ii) in an interface between the silicon carbide substrate (1) and the first oxide silicon film (O) (10).

Abstract: A semiconductor device and a method of manufacturing the same, to appropriately determine an impurity concentration distribution of a field relieving region and reduce an ON-resistance. The semiconductor device includes a substrate, a first drift layer, a second drift layer, a first well region, a second well region, a current control region, and a field relieving region. The first well region is disposed continuously from an end portion adjacent to the vicinity of outer peripheral portion of the second drift layer to a portion of the first drift layer below the vicinity of outer peripheral portion. The field relieving region is so disposed in the first drift layer as to be adjacent to the first well region.

Abstract: It is an object of the present invention to provide a method for manufacturing tantalum carbide which can form tantalum carbide having a prescribed shape using a simple method, can form the tantalum carbide having a uniform thickness even when the tantalum carbide is coated on the surface of an article and is not peeled off by a thermal history, tantalum carbide obtained by the manufacturing method, wiring of tantalum carbide, and electrodes of tantalum carbide. The tantalum carbide is formed on the surface of tantalum or a tantalum alloy by placing the tantalum or tantalum alloy in a vacuum heat treatment furnace, heat-treating the tantalum or tantalum alloy under a condition where a native oxide layer of Ta2O5 formed on the surface of tantalum or tantalum alloy is sublimated to remove the Ta2O5, introducing a carbon source into the vacuum heat treatment furnace, and then heat-treating.

Abstract: Semiconductor devices are provided which have a tensile and/or compressive strain applied thereto and methods of manufacturing. The structure includes a gate stack comprising an oxide layer, a polysilicon layer and sidewalls with adjacent spacers. The structure further includes an epitaxially grown straining material directly on the polysilicon layer and between portions of the sidewalls. The epitaxially grown straining material, in a relaxed state, strains the polysilicon layer.

Abstract: A silicon carbide substrate and a method for manufacturing the silicon carbide substrate are obtained, each of which achieves reduced manufacturing cost of semiconductor devices using the silicon carbide substrate. A method for manufacturing a SiC-combined substrate includes the steps of: preparing a plurality of single-crystal bodies each made of silicon carbide (SiC); forming a collected body; connecting the single-crystal bodies to each other; and slicing the collected body. In the step, the plurality of SiC single-crystal ingots are arranged with a silicon (Si) containing Si layer interposed therebetween, so as to form the collected body including the single-crystal bodies. In the step, adjacent SiC single-crystal ingots are connected to each other via at least a portion of the Si layer, the portion being formed into silicon carbide by heating the collected body. In step, the collected body in which the SiC single-crystal ingots are connected to each other is sliced.

Abstract: A SiC device includes: a substrate; a drift layer; a base region; a source region; a channel layer connecting the drift layer and the source region; a gate oxide film on the channel layer and the source region; a gate electrode on the gate oxide film; an interlayer insulation film with a contact hole having a barrier layer and a BPSG insulation film on the gate electrode; a source electrode having upper and lower wiring electrodes on the interlayer insulation film and in the contact hole for connecting the base region and the source region; and a drain electrode on the substrate. The barrier layer prevents a Ni component in the lower wiring electrode from being diffused into the BPSG insulation film.

Abstract: A main surface of a silicon carbide substrate is inclined by an off angle in an off direction from {0001} plane of a hexagonal crystal. The main surface has such a characteristic that, among emitting regions emitting photoluminescent light having a wavelength exceeding 650 nm of the main surface caused by excitation light having higher energy than band-gap of the hexagonal silicon carbide, the number of those having a dimension of at most 15 ?m in a direction perpendicular to the off direction and a dimension in a direction parallel to the off direction not larger than a value obtained by dividing penetration length of the excitation light in the hexagonal silicon carbide by a tangent of the off angle is at most 1×104 per 1 cm2. Accordingly, reverse leakage current can be reduced.

Abstract: A buffer layer configured of the same conductive semiconductor layers of two or more layers as a drift layer is installed by epitaxial growth between a first semiconductor layer configuring the drift layer that is a layer in which components of the semiconductor device are made and a base substrate including a silicon carbide single crystal wafer. A step of donor concentration is provided at an interface between the drift layer and the buffer layer, an interface between the semiconductor layers configuring the buffer layer, and an interface between the buffer layer and the base substrate and the donor concentration of the drift layer side is lower than that of the base substrate side, thereby making it possible to convert most basal plane dislocations into threading edge dislocations as compared to the drift layer having one layer or the buffer layer configured of one layer.

Abstract: Disclosed herein is a nitride based semiconductor device including: a base substrate; an epitaxial growth layer disposed on the base substrate and generating a 2-dimensional electron gas in an inner portion thereof; and an electrode structure disposed on the epitaxial growth layer, wherein the electrode structure includes: a gate electrode; a source electrode disposed at one side of the gate electrode; and a drain electrode disposed at the other side of the gate electrode and having an extension part extended to the inner portion of the epitaxial growth layer to contact the 2-dimensional electron gas.

Abstract: The present disclosure provides a method for fabricating a semiconductor device that includes forming a gate stack over a silicon substrate, forming dummy spacers on sidewalls of the gate stack, isotropically etching the silicon substrate to form recess regions on either side of the gate stack, forming a semiconductor material in the recess regions, the semiconductor material being different from the silicon substrate, removing the dummy spacers, forming spacer layers having an oxide-nitride-oxide configuration over the gate stack and the semiconductor material, and etching the spacer layers to form gate spacers on the sidewalls of the gate stack.

Abstract: A semiconductor chip of the present invention is a semiconductor device that includes a hexagonal semiconductor layer having anisotropic mechanical properties. A semiconductor chip (21), when viewed from a direction perpendicular to the semiconductor chip (21), has a rectangular shape that has a first side (1A) and a second side (1B) orthogonal to the first side (1A). The amount of thermal deformation along a direction in which the first side (1A) extends and the amount of thermal deformation along a direction in which the second side (1B) extends are substantially equal to each other.

Abstract: An epitaxial structure for an LED is provided. The epitaxial structure includes a patterned epitaxial defect barrier layer disposed over a first portion of a substantially flat substrate to expose a second portion of the substrate. The epitaxial structure also includes a patterned buffer layer over the second portion of the substrate. The epitaxial structure further includes a first semiconductor layer over the patterned buffer layer and the patterned epitaxial defect barrier layer, an active layer over the first semiconductor layer, and a second semiconductor layer over the active layer.

Abstract: A compound semiconductor device includes: a conductive SiC substrate; an AlN buffer layer formed on said conductive SiC substrate and containing Cl; a compound semiconductor buffer layer formed on said AlN layer which contains Cl, said compound semiconductor buffer layer not containing Cl; and a device constituent layer or layers formed above said compound semiconductor buffer layer not containing Cl.

Abstract: A method for manufacturing a semiconductor structure is provided which includes the following steps: a crystalline semiconductor substrate (1) is supplied; a porous region (10) is provided adjacent to a surface (OF) of the semiconductor substrate (1); a dopant (12) is introduced into the porous region (10) from the surface (OF); and the porous region (10) is thermally recrystallized into a crystalline doping region (10?) of the semiconductor substrate (1) whose doping type and/or doping concentration and/or doping distribution are/is different from those or that of the semiconductor substrate (1). A corresponding semiconductor structure is likewise provided.

Abstract: The semiconductor device according to the present invention includes: a semiconductor layer made of SiC; an impurity region formed by doping the semiconductor layer with an impurity; and a contact wire formed on the semiconductor layer in contact with the impurity region, while the contact wire has a polysilicon layer in the portion in contact with the impurity region, and has a metal layer on the polysilicon layer.

Abstract: Disclosed is an RF power FET or HEMT including an electrically-conductive substrate, a grounding metallization layer disposed on a bottom surface of the electrically-conductive substrate, an active area comprising at least one cell including source, gate and drain electrodes disposed over a top surface of the electrically-conductive substrate, and an electrically-conductive shallow trench electrically connecting the source electrode to the grounding metallization layer by way of the electrically-conductive substrate. This configuration results in the effective RF ground being very close to the active area of the FET in order to reduce parasitic source inductance and resistance. This results in potentially higher gain, higher saturation point, higher 3rd-order intercept, more efficient combining of the input RF signal, and more efficient extraction of the output RF signal.

Abstract: A method for manufacturing a silicon carbide substrate achieves reduced manufacturing cost. The method includes the steps of: preparing a base substrate and a SiC substrate; fabricating a stacked substrate by stacking the base substrate and the SiC substrate; fabricating a connected substrate by heating the stacked substrate; transferring a void, formed at a connection interface, in a thickness direction of the connected substrate by heating the connected substrate to cause the base substrate to have a temperature higher than that of the SiC substrate; and removing the void by removing a region including a main surface of the base substrate opposite to the SiC substrate.

Abstract: An embodiment of a process for forming an interface between a silicon carbide (SiC) layer and a silicon oxide (SiO2) layer of a structure designed to conduct current is disclosed. A first epitaxial layer having a first doping level is homo-epitaxially grown on a substrate. The homo-epitaxial growth is preceded by growing, on the first epitaxial layer, a second epitaxial layer having a second doping level higher than the first doping level. Finally, the second epitaxial layer is oxidized so as to be totally removed. Thereby, a silicon oxide layer of high quality is formed, and the interface between the second epitaxial layer and silicon oxide has a low trap density.

Abstract: The present invention provides a silicon carbide substrate, an epitaxial layer provided substrate, a semiconductor device, and a method for manufacturing the silicon carbide substrate, each of which achieves reduced on-resistance. The silicon carbide substrate is a silicon carbide substrate having a main surface, and includes: a SiC single-crystal substrate formed in at least a portion of the main surface; and a base member disposed to surround the SiC single-crystal substrate. The base member includes a boundary region and a base region. The boundary region is adjacent to the SiC single-crystal substrate in a direction along the main surface, and has a crystal grain boundary therein. The base region is adjacent to the SiC single-crystal substrate in a direction perpendicular to the main surface, and has an impurity concentration higher than that of the SiC single-crystal substrate.

Abstract: An intermediate metal film is formed between a Schottky electrode and a pad electrode. A Schottky barrier height between the intermediate metal film and a silicon carbide epitaxial film is equivalent to or higher than a Schottky barrier height between the Schottky electrode and the silicon carbide epitaxial film. By this configuration, an excess current and a leak current through a pin-hole can be suppressed even in the case in which a Schottky barrier height between the pad electrode and the silicon carbide epitaxial film is less than the Schottky barrier height between the Schottky electrode and the silicon carbide epitaxial film.

Abstract: An embedded, strained epitaxial semiconductor material, i.e., an embedded stressor element, is formed at the footprint of at least one pre-fabricated field effect transistor that includes at least a patterned gate stack, a source region and a drain region. As a result, the metastability of the embedded, strained epitaxial semiconductor material is preserved and implant and anneal based relaxation mechanisms are avoided since the implants and anneals are performed prior to forming the embedded, strained epitaxial semiconductor material.

Abstract: An asymmetric hetero-structure FET and method of manufacture is provided. The structure includes a semiconductor substrate and an epitaxially grown semiconductor layer on the semiconductor substrate. The epitaxially grown semiconductor layer includes an alloy having a band structure and thickness that confines inversion carriers in a channel region, and a thicker portion extending deeper into the semiconductor structure at a doped edge to avoid confinement of the inversion carriers at the doped edge.

Abstract: remove impurities from an exposed surface in the ultrahigh vacuum environment. A high qualify single crystalline or polycrystalline silicon carbide film can be grown directly on the sapphire substrate by chemical vapor deposition employing a silicon-containing reactant and a carbon-containing reactant. Formation of single crystalline silicon carbide has been verified by x-ray diffraction, secondary ion mass spectroscopy, and transmission electron microscopy.

Abstract: The present disclosure, which is directed to ultra-thin-body-and-BOX and Double BOX fully depleted SOI devices having an epitaxial diffusion-retarding semiconductor layer that slows dopant diffusion into the SOI channel, and a method of making these devices. Dopant concentrations in the SOI channels of the devices of the present disclosure having an epitaxial diffusion-retarding semiconductor layer between the substrate and SOI channel are approximately 50 times less than the dopant concentrations measured in SOI channels of devices without the epitaxial diffusion-retarding semiconductor layer.

Abstract: A method of fabricating a silicon carbide substrate that can reduce the fabrication cost of a semiconductor device employing the silicon carbide substrate includes the steps of: preparing a SiC substrate made of single crystal silicon carbide; arranging a base substrate in a vessel so as to face one main face of the SiC substrate; forming a base layer made of silicon carbide so as to contact one main face of the SiC substrate by heating a base substrate to a temperature range greater than or equal to a sublimation temperature of silicon carbide constituting the base substrate. In the step of forming a base layer, a silicon generation source made of a substance including silicon is arranged in the vessel, in addition to the SiC substrate and the base substrate.

Abstract: A silicon carbide semiconductor element and a manufacturing method thereof are disclosed in which a low contact resistance is attained between an electrode film and a wiring conductor element, and the wiring conductor element is hardly detached from the electrode film. In the method, a nickel film and a nickel oxide film are laminated in this order on a surface of an n-type silicon carbide substrate or an n-type silicon carbide region of a silicon carbide substrate, followed by a heat treatment under a non-oxidizing condition. The heat treatment transforms a portion of the nickel film into a nickel silicide film. Then, the nickel oxide film is removed with hydrochloric acid solution, and subsequently, a nickel aluminum film and an aluminum film are laminated in this order on a surface of the nickel silicide film.

Abstract: A miniature packaging for a discrete circuit component that comprises a core dice for the circuit component fabricated on a semiconductor substrate. The core dice has at least a pair of metallization electrodes formed on the same or different surfaces of the semiconductor substrate. An end electrode covers a corresponding side surface of the core dice and electrically connects to a corresponding one of the pair of metallization electrodes. The end electrode extends toward the center of the core dice on both the top and bottom surface of the core dice.

Abstract: A method of forming a semiconductor device includes providing a substrate in a vacuum processing tool, the substrate having a strained Ge-containing layer on the substrate and a Si-containing layer on the strained Ge-containing layer, maintaining the substrate at a temperature less than 700° C., and exposing the Si-containing layer to oxidation radicals in an UV-assisted oxidation process to form a Si-containing dielectric layer while minimizing oxidation and strain relaxation in the underlying strained Ge-containing layer. A semiconductor device containing a substrate, a strained Ge-containing layer on the substrate, and a Si-containing dielectric layer formed on the strained Ge-containing layer is provided. The semiconductor device can further contain a gate electrode layer on the Si-containing dielectric layer or a high-k layer on the Si-containing dielectric layer and a gate electrode layer on the high-k layer.

Abstract: A structurally robust power switching assembly, that has a first rigid structural unit, defining a first unit major surface that is patterned to define a plurality of mutually electrically isolated, electrically conductive paths. Also, a similar, second rigid structural unit is spaced apart from the first unit major surface. Finally, a transistor is interposed between and electrically connected to the first unit major surface and the second unit major surface.

Abstract: A method and apparatus for achieving high current gain, and low on-resistance, from a Bipolar Junction Transistor (BJT) in high temperature and high power applications are disclosed. In some embodiments, a thin doped delta layer is inserted at the base emitter junction but inside the base layer. In addition, in some embodiments, a surface recombination layer is inserted between the emitter-base regions of the device. In some embodiments, use of an ion implantation step is avoided to achieve simplicity and low cost of manufacture.

Abstract: A termination configuration of a silicon carbide insulating gate type semiconductor device includes a semiconductor layer of a first conductivity type having a first main face, a gate electrode, and a source interconnection, as well as a circumferential resurf region. The semiconductor layer includes a body region of a second conductivity type, a source region of the first conductivity type, a contact region of the second conductivity type, and a circumferential resurf region of the second conductivity type. A width of a portion of the circumferential resurf region excluding the body region is greater than or equal to ½ the thickness of at least the semiconductor layer. A silicon carbide insulating gate type semiconductor device of high breakdown voltage and high performance can be provided.