Abstract: A transistor arrangement and a method are disclosed. The transistor arrangement includes: a plurality of first semiconductor regions of a first doping type and a plurality of second semiconductor regions of a second doping type, the first semiconductor regions and the second semiconductor regions being arranged alternatingly in a vertical direction of a semiconductor body; a source region adjoining the plurality of first semiconductor regions; a drain region adjoining the plurality of second semiconductor regions and arranged spaced apart from the source region in a first lateral direction; and a plurality of gate regions each of which adjoins at least one of the plurality of second semiconductor regions and is arranged between the source region and the drain region. At least one of the first and semiconductor regions, but less than each of the first and second semiconductor regions has a doping dose that varies in the first lateral direction.

Abstract: A manufacturing method of an electronic device includes: forming a drift layer of an N type; forming a trench in the drift layer; forming an edge-termination structure alongside the trench by implanting dopant species of a P type; and forming a depression region between the trench and the edge-termination structure by digging the drift layer. The steps of forming the depression region and the trench are carried out at the same time. The step of forming the depression region comprises patterning the drift layer to form a structural connection with the edge-termination structure having a first slope, and the step of forming the trench comprises etching the drift layer to define side walls of the trench, which have a second slope steeper than the first slope.

Abstract: A transient voltage suppression device includes a lightly-doped semiconductor structure, a first doped well, a first heavily-doped area, a first buried area, and a second heavily-doped area. The lightly-doped semiconductor structure has a first conductivity type. The first doped well has a second conductivity type and is formed in the lightly-doped semiconductor structure. The first heavily-doped area has the second conductivity type and is formed in the first doped well. The first buried area has the first conductivity type and is formed in the lightly-doped semiconductor structure and under the first doped well, and the first buried area is adjacent to the first doped well. The second heavily-doped area has the second conductivity type and is formed in the lightly-doped semiconductor structure.

Abstract: The present application discloses a method for preparing a semiconductor device structure. The method includes: forming a ring structure over a substrate; performing an etching process to form an annular semiconductor fin under the ring structure; forming a processed area on a top portion of the substrate exposed by the annular semiconductor fin; selectively forming a spacer on a side surface of the annular semiconductor fin; forming a lower source/drain region on the surface of the substrate in contact with a bottom portion of the annular semiconductor fin; forming an inner gate structure in contact with an inner sidewall of the annular semiconductor fin and forming an outer gate structure in contact with an outer sidewall of the annular semiconductor fin; and forming an upper source/drain region on an upper portion of the annular semiconductor fin.

Abstract: A trench etch mask is formed on a process surface of a semiconductor layer. By using the trench etch mask, both first trenches and second trenches are formed that extend from the process surface into the semiconductor layer. The first and second trenches alternate along at least one horizontal direction parallel to the process surface. First semiconductor regions of a first conductivity type are formed in the first trenches. Second semiconductor regions of a second, opposite conductivity type are formed in the second trenches.

Abstract: A semiconductor device includes a first electrode, a second electrode, a first semiconductor region of a first conductivity type that is between the first electrode and the second electrode. A second semiconductor region is adjacent to the first semiconductor region along a first direction and includes a second conductivity type material. A first insulating region is provided within the second semiconductor region. A third electrode is provided on the first semiconductor region via a second insulating region.

Abstract: A static induction transistor is formed on a silicon carbide substrate doped with a first conductivity type. First recessed regions in a top surface of the silicon carbide substrate are filled with epitaxially grown gate regions in situ doped with a second conductivity type. Epitaxially grown channel regions in situ doped with the first conductivity type are positioned between adjacent epitaxial gate regions. Epitaxially grown source regions in situ doped with the first conductivity type are positioned on the epitaxial channel regions. The bottom surface of the silicon carbide substrate includes second recessed regions vertically aligned with the channel regions and silicided to support formation of the drain contact. The top surfaces of the source regions are silicided to support formation of the source contact. A gate lead is epitaxially grown and electrically coupled to the gate regions, with the gate lead silicided to support formation of the gate contact.

Abstract: A method for fabricating a merged p-i-n Schottky (MPS) diode in gallium nitride (GaN) based materials includes providing an n-type GaN-based substrate having a first surface and a second surface. The method also includes forming an n-type GaN-based epitaxial layer coupled to the first surface of the n-type GaN-based substrate, and forming a p-type GaN-based epitaxial layer coupled to the n-type GaN-based epitaxial layer. The method further includes removing portions of the p-type GaN-based epitaxial layer to form a plurality of dopant sources, and regrowing a GaN-based epitaxial layer including n-type material in regions overlying portions of the n-type GaN-based epitaxial layer, and p-type material in regions overlying the plurality of dopant sources. The method also includes forming a first metallic structure electrically coupled to the regrown GaN-based epitaxial layer.

Abstract: A method includes forming isolation regions in a semiconductor substrate to define a first field effect transistor (FET) region, a second FET region, and a diode region, forming a first gate stack in the first FET region and a second gate stack in the second FET region, forming a layer of spacer material over the second FET region and the second gate stack, forming a first source region and a first drain region in the first FET region and a first diode layer in the diode region using a first epitaxial growth process, forming a hardmask layer over the first source region, the first drain region, the first gate stack and a portion of the first diode layer, and forming a second source region and a second drain region in the first FET region and a second diode layer on the first diode layer using a second epitaxial growth process.

Abstract: The purpose of the present invention is to improve the efficiency of conversion between terahertz electromagnetic wave energy and direct current energy via plasma waves in a terahertz electromagnetic wave conversion device with a field effect transistor structure. This invention has an HEMT structure having a substrate, an electron transit layer, an electron supply layer, a source and a drain, and includes a first and second group of gates. The gate length of each finger of the first group of gates is narrower than the gate length of each finger of the second group of gates, and each finger of each group of gates is disposed between the source and the drain on the same cycle. A first and second distance from each finger of the first group of gates to two fingers of the second group of gates adjacent to each finger are unequal lengths.

Abstract: A semiconductor structure includes a GaN substrate having a first surface and a second surface opposing the first surface. The GaN substrate is characterized by a first conductivity type and a first dopant concentration. The semiconductor structure also includes a first GaN epitaxial layer of the first conductivity type coupled to the second surface of the GaN substrate and a second GaN epitaxial layer of a second conductivity type coupled to the first GaN epitaxial layer. The second GaN epitaxial layer includes an active device region, a first junction termination region characterized by an implantation region having a first implantation profile, and a second junction termination region characterized by an implantation region having a second implantation profile.

Abstract: A radiation image pickup apparatus allowed to restore a change in characteristics in a pixel transistors caused by radiation, and a method of driving the same are provided. The radiation image pickup apparatus includes: a pixel section including a plurality of unit pixels and generating an electrical signal based on incident radiation, each of the unit pixels including one or more pixel transistors and a photoelectric conversion element; a drive section for selectively driving the unit pixels of the pixel section; and a characteristic restoring section including a first constant current source for annealing and a selector switch for changing a current path from the unit pixels to the first constant current source at the time of non-measurement of the radiation, and allowing an annealing current to flow through the pixel transistor, thereby restoring characteristics of the pixel transistor.

Abstract: An edge terminated semiconductor device is described including a GaN substrate; a doped GaN epitaxial layer grown on the GaN substrate including an ion-implanted insulation region, wherein the ion-implanted region has a resistivity that is at least 90% of maximum resistivity and a conductive layer, such as a Schottky metal layer, disposed over the GaN epitaxial layer, wherein the conductive layer overlaps a portion of the ion-implanted region. A Schottky diode is prepared using the Schottky contact structure.

Abstract: Vertical junction field effect transistors (VJFETs) having improved heat dissipation at high current flow while maintaining the desirable specific on-resistance and normalized saturated drain current properties characteristic of devices having small pitch lengths are described. The VJFETs comprise one or more electrically active source regions in electrical contact with the source metal of the device and one or more electrically inactive source regions not in electrical contact with the source metal of the device. The electrically inactive source regions dissipate heat generated by the electrically active source regions during current flow.

Abstract: In various embodiments, image sensors include photosensitive pixels, associated vertical CCDs, sense nodes each accepting charge from one or more of the vertical CCDs, and readout circuitry accepting signals from the sense nodes.

Abstract: A semiconductor structure includes a GaN substrate having a first surface and a second surface opposing the first surface. The GaN substrate is characterized by a first conductivity type and a first dopant concentration. The semiconductor structure also includes a first GaN epitaxial layer of the first conductivity type coupled to the second surface of the GaN substrate and a second GaN epitaxial layer of a second conductivity type coupled to the first GaN epitaxial layer. The second GaN epitaxial layer includes an active device region, a first junction termination region characterized by an implantation region having a first implantation profile, and a second junction termination region characterized by an implantation region having a second implantation profile.

Abstract: A semiconductor structure includes a GaN substrate with a first surface and a second surface. The GaN substrate is characterized by a first conductivity type and a first dopant concentration. A first electrode is electrically coupled to the second surface of the GaN substrate. The semiconductor structure further includes a first GaN epitaxial layer of the first conductivity type coupled to the first surface of the GaN substrate and a second GaN layer of a second conductivity type coupled to the first GaN epitaxial layer. The first GaN epitaxial layer comprises a channel region. The second GaN epitaxial layer comprises a gate region and an edge termination structure. A second electrode coupled to the gate region and a third electrode coupled to the channel region are both disposed within the edge termination structure.

Abstract: There is provided a high frequency semiconductor switch for improving insertion loss characteristics and harmonic characteristics by providing good voltage distribution in a gate wiring. The field effect transistor includes a source wiring electrically connected to a source region formed on a substrate and extending unidirectionally; a drain wiring electrically connected to a drain region formed on the substrate and extending in parallel with the source wiring; a gate having a parallel portion extending between the source wiring and the drain wiring in approximately parallel with the source wiring and the drain wiring; a gate wiring applying voltage to the gate; and a gate via electrically connecting the gate to the gate wiring, the parallel portion including two ends and formed with a path applying voltage to each of the two ends from the gate via.

Abstract: A detector device and method of its fabrication are disclosed. Illustratively, an additional via is present through an insulator layer over a gate channel region which is on top of the channel region. The additional via is filled with conductor material. The conductor material is removed to form a chamber leading to one side of the gate channel region. Furthermore, a nanopore is etched from the chamber through the channel region.

Abstract: A method for producing a photosensitive integrated circuit including producing circuit control transistors, producing, above the control transistors, and between at least one upper electrode and at least one lower electrode, at least one photodiode, by amorphous silicon layers into which photons from incident electromagnetic radiation are absorbed, producing at least one passivation layer, between the lower electrode and the control transistors, and producing, between the control transistors and the external surface of the integrated circuit, a reflective layer capable of reflecting photons not absorbed by the amorphous silicon layers.

Abstract: One type of a semiconductor device integrating with a monitoring device is disclosed. The device includes a plurality of gate fingers, two of which arranged in a center of the device has a space wider than a space between any other fingers to suppress the heat concentration on the center of the device. The monitoring region is arranged in this wider space to monitor the temperature dependence of the device.

Abstract: A conductive pattern structure includes a first insulating interlayer on a substrate, metal wiring on the first insulating interlayer, a second insulating interlayer on the metal wiring, and first and second metal contacts extending through the second insulating interlayer. The first metal contacts contact the metal wiring in a cell region and the second metal contact contacts the metal wiring in a peripheral region. A third insulating interlayer is disposed on the second insulating interlayer. Conductive segments extend through the third insulating interlayer in the cell region and contact the first metal contacts. Another conductive segment extends through the third insulating interlayer in the peripheral region and contacts the second metal contact. The structure facilitates the forming of uniformly thick wiring in the cell region using an electroplating process.

Abstract: A vertical-sidewall dual-mesa static induction transistor (SIT) structure includes a silicon carbide substrate having a layer arrangement formed thereon. Laterally spaced ion implanted gate regions are defined in the layer arrangement. Source regions are defined in the layer arrangement. Each of the source regions can include a channel mesa having a source mesa disposed thereon. The source mesa includes upright sidewalls relative to a principal plane of the substrate defining a horizontal dimension thereof. The channel mesa includes upright sidewalls relative to the source mesa and the principal plane of the substrate. Also disclosed is a method of fabricating a vertical-sidewall dual-mesa SiC transistor device. The method includes implanting ions at an angle relative to a principal plane of the substrate to form gate junctions in upper portions of the substrate and lateral portions of the upright channel mesas.

Abstract: A semiconductor structure includes a GaN substrate with a first surface and a second surface. The GaN substrate is characterized by a first conductivity type and a first dopant concentration. A first electrode is electrically coupled to the second surface of the GaN substrate. The semiconductor structure further includes a first GaN epitaxial layer of the first conductivity type coupled to the first surface of the GaN substrate and a second GaN layer of a second conductivity type coupled to the first GaN epitaxial layer. The first GaN epitaxial layer comprises a channel region. The second GaN epitaxial layer comprises a gate region and an edge termination structure. A second electrode coupled to the gate region and a third electrode coupled to the channel region are both disposed within the edge termination structure.

Abstract: A semiconductor device including a substrate, a gate structure, a spacer and source/drain regions is provided. The gate structure is on the substrate, wherein the gate structure includes, from bottom to top, a high-k layer, a work function metal layer, a wetting layer and a metal layer. The spacer is on a sidewall of the gate structure. The source/drain regions are in the substrate beside the gate structure.

Abstract: A field effect transistor is provided having a reduced drain capacitance per unit gate width. A gate electrode 21 (G) having a plurality of sides is formed in first-conductivity first semiconductor region 14. Drain region 18D (D) is formed inside the gate electrode, and source regions 18S (S) are formed in respective regions outside the plurality of sides in widths that do not reduce the corresponding channel widths of the drain region. The gate electrode is formed along all the plurality of sides of the drain region in order to form a transistor.

Abstract: A semiconductor device includes a substrate and a first gate oxide layer overlying a first device region and a second device region in the substrate, a first gate in the first device region, and a second gate and a third gate in the second device region. The device also has a first dielectric layer with a first portion disposed on the first gate, a second portion disposed adjacent a sidewall of the first gate, and a third portion disposed over the third gate. An inter-gate oxide layer is disposed on the first gate and between the first portion and the second portion of the first dielectric layer. A fourth gate overlies the second gate oxide layer, the inter-gate oxide layer, and the first portion and the second portion of the first dielectric layer in the first device region. A fifth gate overlies the third portion of the first dielectric layer which is disposed over the third gate in the second device region.

Abstract: The invention includes a method of forming a semiconductor construction. Dopant is implanted into the upper surface of a monocrystalline silicon substrate. The substrate is etched to form a plurality of trenches and cross-trenches which define a plurality of pillars. After the etching, dopant is implanted within the trenches to form a source/drain region that extends less than an entirety of the trench width. The invention includes a semiconductor construction having a bit line disposed within a semiconductor substrate below a first elevation. A wordline extends elevationally upward from the first elevation and substantially orthogonal relative to the bit line. A vertical transistor structure is associated with the wordline. The transistor structure has a channel region laterally surrounded by a gate layer and is horizontally offset relative to the bit line.

Abstract: A static induction transistor comprising: a region of semiconductor material having a first conductivity type; at least two spaced-apart gate regions formed in the region of semiconductor material, the gate regions having a second conductivity type that is opposite to the first conductivity type; at least one source region having the first conductivity type formed in the region of semiconductor material between the spaced-apart gate regions; a drain region having the first conductivity type formed in the region of semiconductor and spaced-apart from the source region to define a channel region therebetween; and a dielectric carrier separation layer formed at the periphery of the gate regions.

Abstract: An integrated circuit includes N plane-like metal layers. A first plane-like metal layer includes M contact portions that communicate with the N plane-like metal layers, respectively. The first plane-like metal layer and the N plane-like metal layers are located separate planes. First and second drain regions have a symmetric shape across at least one of horizontal and vertical centerlines. First and second gate regions have a first shape that surrounds the first and second drain regions, respectively. First and second source regions are arranged adjacent to and on one side of the first gate region, the second gate region and the connecting region. The first source region, the second source region, the first drain region and the second drain region communicate with at least two of the N plane-like metal layers.

Abstract: A method for making a thin film transistor, the method comprising the steps of: (a) providing a carbon nanotube array and an insulating substrate; (b) pulling out a carbon nanotube film from the carbon nanotube array by using a tool; (c) placing at least one carbon nanotube film on a surface of the insulating substrate, to form a carbon nanotube layer thereon; (d) forming a source electrode and a drain electrode; wherein the source electrode and the drain electrode being spaced therebetween, and electrically connected to the carbon nanotube layer; and (e) covering the carbon nanotube layer with an insulating layer, and a gate electrode being located on the insulating layer.

Abstract: Carrier including: a substrate having a first interface with first contact holes, and a second interface, which lies opposite the first interface, with second contact holes. The substrate includes a substrate body and electrically conductive contact channels formed therein, wherein each of the contact channels electrically conductively connects a first contact hole to a second contact hole. The carrier also includes a front-side wiring layer arranged on the first interface and; has a first front-side metallization layer formed therein such that it includes a first capacitor electrode for electrically connecting microelectronic devices and/or circuits to a first pole of a signal or supply voltage.

Abstract: In a semiconductor apparatus of the present invention, a plurality of circuit components are provided. A first bus interconnects the circuit components. A second bus interconnects the circuit components. A switching unit outputs a select signal that causes each circuit component to select one of the first bus and the second bus when transmitting a signal from one of the circuit components to another. The second bus has a size larger than a size of the first bus.

Abstract: An active region in a semiconductor device is made up of a parallel p-n layer including a first p-semiconductor layer and a first n-semiconductor with the widths and total amounts of impurities being equal to each other to provide a structure in which charges are balanced. A section parallel to stripes in the parallel p-n layer in an inactive region is made up of a second parallel p-n layer including a second p-semiconductor layer, with its width larger than that of the first p-semiconductor layer, and a second n-semiconductor layer with its width smaller than that of the first n-semiconductor layer. The total amount of impurities in the second p-semiconductor layer is made larger than that in the second n-semiconductor layer to provide a structure in which charges are made unbalanced.

Abstract: An integrated circuit comprises a first drain region having a symmetric shape across at least one of horizontal and vertical centerlines. A first gate region has a first shape that surrounds the first drain region. A second drain region has the symmetric shape. A second gate region has the first shape that surrounds the second drain region. A connecting gate region connects the first and second gate regions. A first source region is arranged adjacent to and on one side of the first gate region, the second gate region and the connecting gate region. A second source region is arranged adjacent to and on one side of side of the first gate region, the second gate region and the connecting gate region.

Abstract: A method of manufacturing a local recess channel transistor in a semiconductor device. A hard mask layer is formed on a semiconductor substrate that exposes a portion of the substrate. The exposed portion of the substrate is etched using the hard mask layer as an etch mask to form a recess trench. A trench spacer is formed on the substrate along a portion of sidewalls of the recess trench. The substrate along a lower portion of the recess trench is exposed after the trench spacer is formed. The exposed portion of the substrate along the lower portion of the recess trench is doped with a channel impurity to form a local channel impurity doped region surrounding the lower portion of the recess trench. A portion of the local channel impurity doped region surrounding the lower portion of the recess trench is doped with a Vth adjusting impurity to form a Vth adjusting impurity doped region inside the local channel impurity doped region. The width of the lower portion of the recess trench is expanded.

Abstract: A first gate stack comprising two stacked gate electrodes in a first device region, a second gate stack comprising a metal gate electrode in a second device region, and a third gate stack comprising a semiconductor gate electrode in a third device region are formed by forming and removing portions of a silicon-oxide based gate dielectric layer, a first doped semiconductor layer, an interfacial dielectric layer, a high-k gate dielectric layer, a metal gate layer, and an optional semiconductor material layer in various device regions. The first gate stack may be employed to form a flash memory, and the second and third gate stacks may be employed to form a pair of p-type and n-type field effect transistors.

Abstract: In a semiconductor apparatus of the present invention, a plurality of circuit components are provided. A first bus interconnects the circuit components. A second bus interconnects the circuit components. A switching unit outputs a select signal that causes each circuit component to select one of the first bus and the second bus when transmitting a signal from one of the circuit components to another. The second bus has a size larger than a size of the first bus.

Abstract: An electrically programmable device with embedded EEPROM and method for making thereof. The method includes providing a substrate including a first device region and a second device region, growing a first gate oxide layer in the first device region and the second device region, and forming a first diffusion region in the first device region and a second diffusion region and a third diffusion region in the second device region. Additionally, the method includes implanting a first plurality of ions to form a fourth diffusion region in the first device region and a fifth diffusion region in the second device region. The fourth diffusion region overlaps with the first diffusion region.

Abstract: A semiconductor device, such as a transistor or capacitor, is provided. The device includes a substrate, a gate dielectric over the substrate, and a conductive gate electrode film over the gate dielectric. The gate dielectric includes a mixed rare earth aluminum oxide, nitride or oxynitride film containing aluminum and at least two different rare earth metal elements.

Abstract: An insulated gate silicon carbide semiconductor device is provided having small on-resistance. The device combines a static induction transistor structure with an insulated gate field effect transistor structure. The advantages of both the SIT structure and the insulated gate field effect transistor structure are obtained. The structures are formed on the same SiC semiconductor substrate, with the MOSFET structure above the SIT structure. The SIT structure includes a p+ gate region in an n-type drift layer on an n+ SiC semiconductor substrate, and an n+ first source region on the surface of the drift layer. The MOSFET structure includes a p-well region on the surface of the first source region, a second source region formed in the p-well region, and a MOS gate structure formed in a trench extending from the second source region to the first source region. The p+ gate region and a source electrode are conductively connected.

Abstract: A vertical transistor having an annular transistor body surrounding a vertical pillar, which can be made from oxide. The transistor body can be grown by a solid phase epitaxial growth process to avoid difficulties with forming sub-lithographic structures via etching processes. The body has ultra-thin dimensions and provides controlled short channel effects with reduced need for high doping levels. Buried data/bit lines are formed in an upper surface of a substrate from which the transistors extend. The transistor can be formed asymmetrically or offset with respect to the data/bit lines. The offset provides laterally asymmetric source regions of the transistors. Continuous conductive paths are provided in the data/bit lines which extend adjacent the source regions to provide better conductive characteristics of the data/bit lines, particularly for aggressively scaled processes.

Abstract: A method of manufacturing a local recess channel transistor in a semiconductor device. A hard mask layer is formed on a semiconductor substrate that exposes a portion of the substrate. The exposed portion of the substrate is etched using the hard mask layer as an etch mask to form a recess trench. A trench spacer is formed on the substrate along a portion of sidewalls of the recess trench. The substrate along a lower portion of the recess trench is exposed after the trench spacer is formed. The exposed portion of the substrate along the lower portion of the recess trench is doped with a channel impurity to form a local channel impurity doped region surrounding the lower portion of the recess trench. A portion of the local channel impurity doped region surrounding the lower portion of the recess trench is doped with a Vth adjusting impurity to form a Vth adjusting impurity doped region inside the local channel impurity doped region. The width of the lower portion of the recess trench is expanded.

Abstract: A field-effect transistor includes a substrate of a first conductivity type, and a channel diffusion region of a second conductivity type provided in the first conductivity type substrate. The transistor also includes a first conductivity type contact region provided in the second conductivity type channel diffusion region, and an electrode wiring connected to the first conductivity type source contact region and second conductivity type source contact region. A surface insulating film is provided on the second conductivity type channel diffusion region. A plurality of linear gate electrodes are provided on the surface insulating film. The gate electrodes are parallel to each other. The spacing between the gate electrodes is less than the thickness of the surface insulating film.

Abstract: A high-breakdown-voltage semiconductor device comprises a high-resistance semiconductor layer, trenches formed on the surface thereof in a longitudinal plane shape and in parallel, first regions formed on the semiconductor layer to be sandwiched between adjacent ones of the trenches and having an impurity concentration higher than that of the semiconductor layer, a second region having opposite conductivity to the first regions and continuously disposed in a trench sidewall and bottom portion, a sidewall insulating film disposed on the second region of the trench sidewall, a third region disposed on the second region of the trench bottom portion and having the same conductivity as and the higher impurity concentration than the second region, a fourth region disposed on the back surface of the semiconductor layer, a first electrode formed on each first region, a second electrode connected to the third region, and a third electrode formed on the fourth region.

Abstract: The superjunction semiconductor device includes a drain drift section, which includes a first alternating conductivity type layer formed of first n-type regions and first p-type regions arranged alternately. The device also includes a peripheral section around the drain drift section, which includes a second alternating conductivity type layer formed of second n-type regions and second p-type regions arranged alternately. The peripheral section further includes a third alternating conductivity type layer in its surface portion. The third alternating conductivity type layer is formed of third n-type regions and third p-type regions arranged alternately. At least the peripheral section is configured to improve the avalanche withstanding capability over the entire device.

Abstract: A junction field effect transistor (JFET) with a reduced gate capacitance. A gate definition spacer is formed on the wall of an etched trench to establish the lateral extent of an implanted gate region for a JFET. After implant, the gate is annealed. In addition to controlling the final junction geometry and thereby reducing the junction capacitance by establishing the lateral extent of the implanted gate region, the gate definition spacer also limits the available diffusion paths for the implanted dopant species during anneal. Also, the gate definition spacer defines the walls of a second etched trench that is used to remove a portion of the p-n junction, thereby further reducing the junction capacitance.

Abstract: A method and structure for a composite trench fill for silicon electronic devices. On a planar silicon substrate having a first deposited layer of oxide and a second deposited layer of polysilicon, a trench is etched. Deposition and etch processes using a combination of oxide and polysilicon are used to fabricate a composite trench fill. The trench bottom and a lower portion of the walls are covered with oxide. The remaining portion of the trench volume is filled with polysilicon. The method may be used for junction field effect transistors (JFETs) and metal oxide semiconductor field effect transistors (MOSFETs).

Abstract: A semiconductor apparatus includes a MOS transistor having a semiconductor substrate providing as a channel region between a source and a drain. A gate electrode is formed on the semiconductor substrate via a gate oxide film. A threshold voltage of the source side region of the MOS transistor is higher than that of the drain side region in a longitudinal direction of the channel region so that a saturation drain current can be constant and a ? performance can be improved while suppressing channel width and length.

Abstract: A Schottky barrier rectifier, in accordance with embodiments of the present invention, includes a first conductive layer and a semiconductor. The semiconductor includes a first doped region, a second doped region and a plurality of third doped regions. The second doped region is disposed between the first doped region and the first conductive layer. The plurality of third doped regions are disposed in the second doped region. The first doped region of the semiconductor is heavily doped with a first type of dopant (e.g., phosphorous or arsenic). The second doped region is moderately doped with the first type of dopant. The plurality of third doped regions are moderately to heavily doped with a second type of dopant.