Abstract: A wiring line to which a high-frequency signal is applied is electrically connected in parallel to an auxiliary wiring line via a plurality of contact holes. The contact holes are formed through an interlayer insulating film and arranged in vertical direction to the wiring line. Since the auxiliary wiring line is formed in the same layer as an electrode that constitutes a TFT, the electric resistance of the wiring line can be reduced effectively and waveform rounding of an applied high-frequency signal can be reduced without increasing the number of manufacturing steps.

Abstract: The invention provides a semiconductor memory device comprising a plurality of word lines, a plurality of bit lines, and a plurality of static memory cells each having a first, second, third, fourth, fifth, and sixth transistors. While each of channels of the first, second, third, and fourth transistors are formed vertical against a substrate of the semiconductor memory device. Each of semiconductor regions forming a source or a drain of the fifth and sixth transistors forms a PN junction against the substrate. According to another aspect of the invention, the SRAM device of the invention has a plurality of SRAM cells, at least one of which is a vertical SRAM cell comprising at least four vertical transistors onto a substrate, and each vertical transistor includes a source, a drain, and a channel therebetween aligning in one aligning line which penetrates into the substrate surface at an angle greater than zero degree.

Abstract: A method of fabrication a polysilicon layer is provided. A substrate is provided and then a buffer layer having a plurality of trenches thereon is formed over the substrate. Thereafter, an amorphous silicon layer is formed over the buffer layer. Finally, a laser annealing process is conducted so that the amorphous silicon layer melts and crystallizes into a polysilicon layer starting from the upper reach of the trenches. This invention can be applied to fabricate the polysilicon layer of a low temperature polysilicon thin film transistor liquid crystal display such that the crystals inside the polysilicon layer are uniformly distributed and have a larger average size.

Abstract: A method of controlling the capacitance of the TFT-LCD storage capacitor is provided. The gate dielectric layer of the TFT is composed of a silicon nitride layer, a dielectric layer and a silicon nitride layer, and the etching selectivity of the amorphous silicon layer over the dielectric layer is not less than about 5.0. Therefore, the dielectric layer can be an etching stop layer when a doped and an undoped amorphous silicon layers are etched to form source/drain stacked layers or a conductive layer is etched to form a gate on the gate dielectric layer. Hence, the dielectric layer thickness can be controlled; thereby the capacitance of the storage capacitor can be controlled.

Abstract: In a method for manufacturing a semiconductor device and devices formed thereby, a semiconductor material layer (e.g., amorphous silicon or microcrystallized silicon film) is formed on a substrate. At least a region of the semiconductor material layer is irradiated with a laser for heating and melting the semiconductor material in the region. The manufacturing method is controlled to promote uniform cooling of the semiconductor material in the irradiated region. Uniform cooling of the semiconductor material after irradiation is promoted so that, after irradiation, a desirable polycrystalline microstructure is formed in the semiconductor material layer by lateral solidification from a boundary of the region.

Abstract: The effect of resist poisoning may be eliminated or at least substantially reduced in the formation of a low-k metallization layer, in that a nitrogen-containing barrier/etch stop layer is provided with a significantly reduced nitrogen concentration at an interface in contact with said low-k dielectric material. Consequently, diffusion of nitrogen and nitrogen compounds in vias formed in said low-k dielectric layer is significantly suppressed, so that in a subsequent photolithographic step, interaction of nitrogen and nitrogen compounds with the photoresist is remarkably reduced.

Abstract: The radiation emitter device of the present invention includes at least two radiation emitters emitting radiation of different wavelengths, first and second electrical leads electrically coupled to at least one of the radiation emitters, and an encapsulant configured to encapsulate the radiation emitters and a portion of the first and second electrical leads. The encapsulant is further configured to have a surface defining an optical lens including a plurality of concentric circular grooves. The optical lens is preferably a divergent lens. Preferably, the lens is a multi-faceted Fresnel lens structure having a plurality of risers and Fresnel facets defining the plurality of concentric circular grooves. The radiation emitter device may further include a secondary reflective cup, preferably a parabolic or elliptical reflective cup, disposed proximate the encapsulant about the periphery of the Fresnel lens structure.

Abstract: Semiconductor chip, particularly a radiation-emitting semiconductor chip, comprising an active thin-film layer (2) wherein a photon-emitting zone (3) is formed, and a carrier substrate (1) for the thin-film layer (2) that is arranged at a side of the thin-film layer (2) that faces away from the emission direction and that is connected thereto. At least one cavity (8) by means of which a plurality of mesas (4) is fashioned at the boundary between carrier substrate (1) and thin-film layer (2) is fashioned in the active thin-film layer (2) proceeding from the carrier substrate (1).

Abstract: An optical semiconductor device comprises a semiconductor laser (11) including a lower clad layer, an active layer (4), and an upper layer formed in this order, an electroabsorptive modulator (12) including the lower clad, a light absorption layer (6), and the upper clad layer formed in this order, and a separation region (13) provided between the semiconductor laser and the electroabsorptive modulator. The upper clad layer extends from the semiconductor laser through the separation region to the electroabsorptive modulator and up to the side of the separation region.

Abstract: An LED with improved current spreading structures that provide enhanced current injection into the LED's active layer, improving its power and luminous flux. The current spreading structures can be used in LEDs larger than conventional LEDs while maintaining the enhanced current injection. The invention is particularly applicable to LEDs having insulating substrates but can also reduce the series resistance of LEDs having conductive substrates. The improved structures comprise conductive fingers that form cooperating conductive paths that ensure that current spreads from the p-type and n-type contacts into the fingers and uniformly spreads though the oppositely doped layers. The current then spreads to the active layer to uniformly inject electrons and holes throughout the active layer, which recombine to emit light.

Abstract: The semiconductor laser device has the lower clad layer, active layer, upper clad layer, contact layer, the insulating film, and the positive electrode sequentially formed on the semiconductor substrate. The upper clad layer, the contact layer and the insulating film form the ridge. The positive electrode covers the upper and side faces of the ridge. The thickness of the positive electrode on the upper and side faces of the ridge is preferably substantially the same and it is not less than 150 nm.

Abstract: A packaging material used for a display device which is a desiccative-containing adhesive agent. The desiccative-containing adhesive agent is composed of a liquid-state organic material selected from a group including epoxy resin, polyurethane, bakelite, polyamide, acrylic resin and polysiloxane, and a solid-state desiccative selected from a group including alkaline metal oxide, alkaline-earth metal oxide, metallic halide, barium oxide, calcium oxide, calcium sulfate, calcium chloride, lithium chloride, calcium bromide, potassium Carbonate, aluminum oxide, magnesium oxide, copper sulfate, zinc chloride, zinc bromide, cobalt chloride, silica gel, zeolite and molecular sieve.

Abstract: The wavelength-converting casting composition is based on a transparent epoxy casting resin with a luminous substance admixed. The composition is used in an electroluminescent component having a body that emits ultraviolet, blue or green light. An inorganic luminous substance pigment powder with luminous substance pigments is dispersed in the transparent epoxy casting resin. The luminous substance is a powder of Ce-doped phosphors and the luminous substance pigments have particle sizes ≦20 &mgr;m and a mean grain diameter d50≦5 &mgr;m.

Abstract: A new method is provided to provide the underfill for flip-chip semiconductor devices. An IC chip is provided with solder bumps. The flip-chip is inserted into a cavity, the heatsink forms the top of the cavity, a IC substrate forms the bottom of the cavity. The cavity is filled with a molding compound. This molding compound is forced around and under the IC chip, surrounding the IC chip including the area below the IC chip.

Abstract: A new gate-controlled, negative resistance diode device is achieved. The device comprises, first, a semiconductor layer in a substrate. The semiconductor layer contains an emitter region and a barrier region. The barrier region is in contact with the emitter region and is laterally adjacent to the emitter region. The semiconductor layer contains a collector region. A drift region comprises the semiconductor layer between the barrier region and the collector region. Finally, a gate comprises a conductor layer overlying the drift region, the barrier region, and at least a part of the emitter region with an insulating layer therebetween. A method of manufacture is achieved.

Abstract: A non-doped n-type boron carbide semiconductor polytype and a method of fabricating the same is provided. The n-type boron carbide polytype may be used in a device for detecting neutrons, electric power conversion, and pulse counting. Such a device may include an n-type boron carbide layer coupled with a substrate where the boron carbide may be an electrically active part of the device. This n-type boron carbide layer may be fabricated through the use of closo-1,7-dicarbadodecaborane (metacarborane). Specifically, the non-doped n-type polytype may be fabricated using SR-CVD by placing the substrate in a vacuum chamber, cooling the substrate, introducing metacarborane into the chamber, adsorbing the metacarborane onto the surface of the substrate through the use of incident X-ray radiation or electron beam irradiation, decomposing the adsorbed metacarborane, and allowing the substrate to reach ambient temperature. The n-type polytype of the present invention may also be fabricated by PECVD.

Abstract: A method for forming first and second linear structures of a first composition that meet at right angles, there being a gap at the point at which the structures meet. The linear structures are constructed on an etchable crystalline layer having the first composition. First and second self-aligned nanowires of a second composition are grown on this layer and used as masks for etching the layer. The self-aligned nanowires are constructed from a material that has an asymmetric lattice mismatch with respect to the crystalline layer. The gap is sufficiently small to allow one of the structures to act as the gate of a transistor and the other to form the source and drain of the transistor. The gap can be filled with electrically switchable materials thereby converting the transistor to a memory cell.

Abstract: A bipolar transistor structure and process technology is described incorporating a emitter, a base, and a collector, with most of the intrinsic base adjacent the collector having a graded energy bandgap and a layer of the intrinsic base adjacent the emitter having a substantially constant energy bandgap. The invention has a smaller base transit time than a conventional graded-base-bandgap bipolar transistor.

Abstract: The present invention is a metal bond pad that provides electrical and mechanical connection to an integrated circuit (IC). The metal bond pad is configured to accommodate for probe travel during probing measurements, without modifying the size of the passivation opening of the bond pad. This enables higher density of active devices on the IC and therefore increases integration and lowers IC cost. The metal bond pad for the integrated circuit includes a substrate, a first metal layer, and a second metal layer. The substrate has the first metal layer disposed therein, having an opening from the top surface of the substrate. The second metal layer has a first-end portion, a second-end portion and a center portion disposed between the first-end portion and the second-end portion. The center portion of the second metal layer is aligned with the opening in the substrate and a bottom surface of the center portion is in contact with the top surface of the first metal layer.

Abstract: A method and a multijunction solar device having a high band gap heterojunction middle solar cell are disclosed. In one embodiment, a triple-junction solar device includes bottom, middle, and top cells. The bottom cell has a germanium (Ge) substrate and a buffer layer, wherein the buffer layer is disposed over the Ge substrate. The middle cell contains a heterojunction structure, which further includes an emitter layer and a base layer that are disposed over the bottom cell. The top cell contains an emitter layer and a base layer disposed over the middle cell.

Abstract: An input and output circuit of a semiconductor device is disclosed having an output buffer including first and second pull-up transistors connected in series between the power supply voltage and the pad, first and second pull-down transistors connected in series between the pad and the ground voltage, a pre-driver for pulling up or down a voltage of the pad when an output enable signal is enabled and for switching off the first and second pull-up transistors and the first and second pull-down transistors when the output enable signal is disabled, and a first circuit for adjusting voltage differences between respective gates and respective sources/drains of the first and second pull-up transistors and the first and second pull-down transistors to be below a predetermined voltage level in response to the first, second and third control signals under power on or power off conditions; and an input buffer including a transmission gate for transmitting an input signal applied to the pad to a first node in response

Abstract: A voltage level shifter includes a front stage circuit periodically generating a first control signal and a second control signal in response to a first input clock signal and a second input clock signal complementary to the first input clock signal; a switch circuit including two PMOS transistors connected between a maximum voltage and a minimum voltage in series, wherein a third control signal is outputted from a conjunction of the two PMOS transistors, and the first and second control signals are coupled to the gate electrodes of the two PMOS transistors, respectively; and a driving circuit receiving the third control signal and outputting an output clock signal having a peak-to-peak value larger than a peak-to-peak value of the input clock signal. The voltage level shifter is implemented by essentially PMOS transistors.

Abstract: Provided are a nitride semiconductor field effect transistor (FET) and a method of fabricating the nitride semiconductor FET. The nitride semiconductor FET includes a first semiconductor layer, a second semiconductor layer, a two-dimensional electron gas layer, a T-shaped gate, and a source/drain ohmic electrode. The first semiconductor layer is formed on a substrate. The second semiconductor layer is formed on the first semiconductor layer and has a bandgap energy that is different from the bandgap energy of the first semiconductor layer. The two-dimensional electron gas layer is formed of a hetero-junction of the first semiconductor layer and the second semiconductor layer in an interfacial area between the first semiconductor layer and the second semiconductor layer. The T-shaped gate is formed on the second semiconductor layer and is connected to the second semiconductor layer.

Abstract: Semiconductor memory devices are provided that comprise unit memory cells. The unit memory cells include a first planar transistor in a semiconductor substrate, a vertical transistor disposed on the first planar transistor and a second planar transistor in series with the first planar transistor. The first planar transistor and the second planar transistor may have different threshold voltages. The semiconductor memory device may further include word lines. One of these word lines may form the gate of the second planar transistor a unit memory cell.

Abstract: For forming a gate electrode, a conductive film with low resistance including Al or a material containing Al as its main component and a conductive film with low contact resistance for preventing diffusion of Al into a semiconductor layer are laminated, and the gate electrode is fabricated by using an apparatus which is capable of performing etching treatment at high speed.

Abstract: A CMOS image sensor for improving a characteristic of transmittance therein is provided by forming a convex-shaped color filter pattern that acts as a micro-lens. The CMOS image sensor includes a semiconductor structure having a photodiode and a peripheral circuit, an insulating layer that is formed on the semiconductor structure and that has a trench, and a convex-shaped color filter pattern formed on the insulating layer and covering the trench.

Abstract: A semiconductor device having a semiconductor substrate; an insulating film formed on said semiconductor substrate; a ferroelectric capacitor having a lower electrode, a ferroelectric film and an upper electrode which are stacked sequentially on the insulating film; a first hydrogen barrier film; a first inter-layer insulating film covering said ferroelectric capacitor; and a second inter-layer insulating film stacked on the first inter-layer insulating film, the first hydrogen barrier film being interposed between the first and second interlayer insulating films is proposed.

Abstract: A magnetic memory includes digit lines, bit lines, and magnetic tunnel junctions (MTJs) that are between the bits lines and the digit lines. The digit lines intersect the bit lines at an oblique angle. The digit lines may intersect the bit lines at an oblique angle of from 15° to 75°.

Abstract: The present invention avoids leakage in semiconductors, such as dynamic random access memory (DRAM) devices, caused by word line/bit line shorts by locating transistors (e.g., isolator, current limiter, equalize) inside isolated p-wells.

Abstract: Provided is, for example, a method for the fabrication of electrical interconnects in semiconductor devices wherein a substrate including two or more transistors having gate regions wherein the gate regions are not exposed (e.g., the gate regions are completely covered by an insulating cap) is provided. An insulating layer overlying the transistors and the active areas is deposited, where upon a hard mask is created and patterned to form a contact plug/interconnect opening over a first active area and a portion of a first transistor immediately adjacent the first active area. A spacer is formed within the contact plug/interconnect opening. Insulating material overlying active areas between transistors is removed. A portion of the gate region of the first transistor is then exposed and interconnect material is deposited within the contact plug/interconnect opening onto the exposed portion of the gate region of the first transistor and the first active area.

Abstract: A memory device includes a coupling capacitor and a field-effect transistor. The coupling capacitor is formed from (1) a first dopant region in a second dopant region on a substrate, (2) a gate dielectric atop the first dopant region, and (3) a first gate conductor atop the gate dielectric. The coupling capacitor has the first gate conductor coupled to a second gate conductor of the field-effect transistor. A voltage can be applied to the second dopant region to isolate the coupling capacitor from the substrate by reverse biasing a PN junction formed between the first dopant region and the second dopant region.

Abstract: An object of the present invention is to provide a semiconductor memory device suitable for larger-capacity storage because of its ability to store 3 or more bits in one element and capable of a high-speed and high-efficiency write operation due to a reduced leakage current during the write operation and provide a fabrication method therefor. According to the present invention, each of elements has a source region, a drain region, a control gate, two charge storage regions, and one or more assist gates. During a write operation, source side injection writing is performed with respect to a write target element by using the assist gates, while adjacent elements are isolated by field isolation using the assist gates.

Abstract: The present invention includes a method of constructing a novel capacitor and geometry for the capacitor. The method and device include forming a multilayer structure having what generally can be described as a wave shape. Particular aspects of the present invention are described in the claims, specification and drawings.

Abstract: A memory cell includes: a trench capacitor, including a trench silicon layer having an upper portion and a lower portion, and a buried plate disposed adjacent the lower portion of the trench silicon layer; an array FET having a gate portion, a drain portion, a source portion, and a buried strap coupled to one of the source and drain portions, the buried strap being in communication with the upper portion of the trench silicon layer; and a collar disposed about the upper portion of the trench silicon layer and between the buried strap and the buried plate, the collar including a re-entrant bend that is operable to decrease an electric field between the buried strap and the buried plate.

Abstract: A capacitor includes an upper electrode formed by physical vapor deposition and chemical vapor deposition. The upper electrode of the capacitor may include a first upper electrode formed by chemical vapor deposition and a second upper electrode formed by physical vapor deposition. Alternatively, the upper electrode may include a first upper electrode formed by physical vapor deposition and a second upper electrode formed by chemical vapor deposition. The upper electrode of the capacitor is formed through two steps using chemical vapor deposition and physical vapor deposition. Therefore, the upper electrode can be thick and rapidly formed, whereby electrical characteristics of the upper electrode are not deteriorated.

Abstract: A semiconductor nonvolatile memory cell (30) comprising a split-gate FET device having a charge-storage transistor (38) in series with a select transistor (39). A multilayered charge-storage gate dielectric (35) extends over at least a portion of the source (32) and a first portion (341) of the channel of the FET. A select gate dielectric (36), contiguous to the charge-storage gate dielectric, extends over at least a portion of the drain (33) and a second portion (342) of the channel. A monolithic gate conductor (37) overlies both the charge-storage gate dielectric and the select gate dielectric. In an embodiment, the charge-storage gate dielectric is an ONO stack that incorporates a thin-film nitride charge-storage layer (352). The select transistor operates to inhibit over-erasure of the NVM cell. The thin-film nitride charge-storage layer extends laterally over a substantial portion of the channel so as to enhance data retention by the cell.

Abstract: A method of manufacturing a metal oxide semiconductor. A gate structure of the metal oxide semiconductor is etched. A nitrogen-comprising gas, which may be NO or N2O, is made to flow over the metal oxide semiconductor. A pre-implant film is grown over the edges of the gate structure. The pre-implant film may repair damage to a gate stack edge caused by an etching process. The film may be substantially silicon nitride. Beneficially, such a film may be thinner than a conventional silica oxide film. A thinner film does not deleteriously contribute to non-uniformities in a tunnel oxide. A non-unifonn tunnel oxide may result in a non-uniform field between a gate and a channel. Non-uniform fields may have numerous deleterious effects. Advantageously, embodiments of the present invention overcome prior art deficiencies in repairing gate stack edge defects.

Abstract: A single-poly EEPROM cell is disclosed with a vertically formed metal-insulator-metal (MIM) coupling capacitor, which serves as a control gate in place of a laterally buried control gate thereby eliminating the problem of junction breakdown, and at the same time reducing the size of the cell substantially. A method of forming the single-poly cell is also disclosed. This is accomplished by forming a floating gate over a substrate with an intervening tunnel oxide and then the MIM capacitor over the floating gate with another intervening dielectric layer between the top metal and the lower metal of the capacitor where the latter metal is connected to the polysilicon floating gate.

Abstract: A composite floating gate structure in flash memory cells is disclosed. Parallel active regions separated by isolation regions that extend from the surface of a semiconductor region of a substrate into the semiconductor region. A gate dielectric layer is disposed over the active regions. Planar parts of composite floating gates are composed of a first conductive layer and are equally spaced along the active regions where they are disposed over the gate dielectric layer. Spacer like parts of composite floating gates are composed of a second conductive layer and are disposed over the planar parts along both edges of edges planar parts so that sidewalls of the spacer like parts are parallel to the active regions. The spacer like parts and the planar parts compose the composite floating gates. An interlevel dielectric layer is patterned into equally spaced parallel stripes perpendicular to the active regions and each stripe is disposed over the corresponding composite floating gate for each active region.

Abstract: Flash memory is rapidly decreasing in price. There is a demand for a new memory system that permits size reduction and suits multiple-value memory. A flash memory of AND type suitable for multiple-value memory with multiple-level threshold values can be made small in area if the inversion layer is utilized as the wiring; however, it suffers the disadvantage of greatly varying in writing characteristics from cell to cell. Another promising method of realizing multiple-value memory is to change the storage locations. This method, however, poses a problem with disturbance at the time of operation. The present invention provides one way to realize a semiconductor memory device with reduced cell-to-cell variation in writing characteristics.

Abstract: A NAND type semiconductor device is disclosed, in which a first insulating film embedded between the memory cell gates and between the memory cell gates and the selecting gate does not contain nitrogen as a major component, a second insulating film is formed on the first insulating film, and an interlayer insulating film is formed on the second insulating film whose major component is different from a manor component of the second insulating film.

Abstract: A flash memory device includes a substrate having a trench, a deep N-type well region in the substrate, a stacked gate structure on the substrate, a first and a second spacer on a sidewall of the stacked gate, wherein the first spacer is connected with the top of the trench, a source region in the substrate under the first spacer, a drain region in the substrate under the second spacer, a P-type well region between the stacked gate and the deep N-type well region, wherein the junction between the two well regions is higher than the bottom of the trench, a doped region along the bottom and the sidewall of the trench, wherein this doped region is connected with the source region and isolates the P-type well region from the contact formed in the trench, the contact being electrically connected to the source region.

Abstract: A self aligned method of forming a semiconductor memory array of floating gate memory cells in a semiconductor substrate having a plurality of spaced apart isolation regions and active regions on the substrate substantially parallel to one another in the column direction, and an apparatus formed thereby. Floating gates are formed in each of the active regions. In the row direction, trenches are formed that include indentations or different widths. The trenches are filled with a conducting material to form blocks of the conducting material that constitute source regions with a first portion that is disposed adjacent to but insulated from the floating gate, and a second portion that this disposed over but insulated from the floating gate.

Abstract: A structure of a flash memory, having a deep P-well formed in an N-type substrate, an N-well formed in the deep P-well, a stacked gate structure formed on the substrate, an N-type source region and an N-type drain region formed in an N-well at two respective sides of the stacked gate, where the N-type source region is in electric contact with the N-well, a P-well formed in the N-well to encompass the N-type source region and to extend towards the N-type drain region through the portion under the stacked gate, and a contact window formed at the junction of the N-type source region and the P-well to electrically short circuit the N-type source region and the P-well. The flash memory uses F-N tunneling effect for programming and the channel F-N tunneling effect to perform the erase operation.

Abstract: A finger-like floating gate structure in flash memory cells is disclosed. Raised isolation regions within a semiconductor region separate parallel active regions. A gate dielectric layer is disposed over the active regions. Finger-like floating gates are equally spaced along the active regions. The finger-like floating gates are comprised of a conductive base section that is disposed over the gate dielectric layer and three conductive finger sections that are in intimate electrical contact with the base section. An interlevel dielectric layer is patterned into equally spaced parallel stripes perpendicular to the active regions and each stripe is disposed over the corresponding composite floating gate for each active region. Word lines, which are composed of a third conductive layer, are parallel lines disposed over the interlevel dielectric layer and serve as control gates.

Abstract: A method of making an electronic device comprising the steps of: providing a plurality of wafers, each wafer comprising a bonding surface; etching one or more trenches into one or more bonding surfaces, the trenches substantially perpendicular to a preferred direction of diffusion along one or more of the bonding surfaces; rendering the bonding surfaces hydrophobic; and bonding the bonding surfaces together by direct wafer bonding. A semiconductor structure comprising a plurality of wafers, each wafer comprising a bonding surface, one or more bonding surfaces comprising one or more trenches substantially perpendicular to a preferred direction of diffusion along one or more of the bonding surfaces; and the bonding surfaces bonded together by a direct wafer bonding interface.

Abstract: In accordance with an embodiment of the invention, a semiconductor structure includes a semiconductor region having a P-type region and a N-type region forming a PN junction therebetween. A first trench extends in the semiconductor region adjacent at least one of the P-type and N-type regions. The first trench includes at least one diode therein.

Abstract: A power semiconductor device includes trenches disposed in a first base layer of a first conductivity type at intervals to partition main and dummy cells, at a position remote from a collector layer of a second conductivity type. In the main cell, a second base layer of the second conductivity type, and an emitter layer of the first conductivity type are disposed. In the dummy cell, a buffer layer of the second conductivity type is disposed. A gate electrode is disposed, through a gate insulating film, in a trench adjacent to the main cell. A buffer resistor having an infinitely large resistance value is inserted between the buffer layer and emitter electrode. The dummy cell is provided with an inhibiting structure to reduce carriers of the second conductivity type to flow to and accumulate in the buffer layer from the collector layer.

Abstract: A P-well region and an N-well region are formed in an upper layer of a silicon wafer. A shallow trench having a depth of 0.05 &mgr;m to 0.1 &mgr;m is formed in the vicinity of a boundary between the P-well region and the N-well region. A gate oxide film is formed on an entire surface of the silicon wafer. On a bottom of the shallow trench of the P-well region and the outer layer of the silicon wafer contacting the upper ends of the sidewall of the shallow trench are formed n+-diffusion layers. On the bottom of the shallow trench of the N-well region and the outer layer of the silicon wafer contacting the upper ends of the sidewall of the shallow trench are formed p+-diffusion layers. On the sidewalls of the shallow trench, gate electrodes are formed through the gate oxide film. A silicon oxide film is formed so as to cover the gate electrodes. Electrodes contacting the diffusion layers are formed through the silicon oxide film.

Abstract: The present invention relates to a metal-semiconductor contact comprising a semiconductor layer and comprising a metallization applied to the semiconductor layer, a high dopant concentration being introduced into the semiconductor layer such that a non-reactive metal-semiconductor contact is formed between the metallization and the semiconductor layer. The metallization and/or the semiconductor layer are formed in such a way that only a fraction of the introduced doping concentration is electrically active, and a semiconductor layer doped only with this fraction of the doping concentration only forms a Schottky contact when contact is made with the metallization. Furthermore, the invention relates to a semiconductor component comprising a drain zone, body zones embedded therein and source zones again embedded therein. The semiconductor component has metal-semiconductor contacts in which the contacts made contact only with the source zones but not with the body zones.