Abstract: A method for producing a semiconductor component includes: forming a silicon carbide substrate having a body layer formed on a section of a main layer, and a source layer formed on a section of the body layer; forming gate trenches and contact trenches extending through the source layer and the body layer, the gate trenches and contact trenches alternating along a first horizontal direction parallel to a first main surface of the silicon carbide substrate; forming a gate dielectric in the gate trenches; forming a metal structure which includes first sections adjoining the gate dielectric in the gate trenches and second sections in the contact trenches, the second sections adjoining body regions formed from sections of the body layer and source regions formed from sections of the source layer; and removing third sections of the metal structure that connect the first sections to the second sections.

Abstract: Embodiments of present invention provide a semiconductor structure. The semiconductor structure includes a plurality of sections from a top to a bottom thereof, wherein the plurality of sections has a same chemical composition and at least two different strains. For example, in one embodiment, the plurality of sections has a same chemical composition of epitaxially grown silicon (Si) and has alternating strains between a tensile strain and a compressive strain. A method of manufacturing the semiconductor structure is also provided.

Abstract: A method for fabricating a semiconductor device including vertical transport fin field-effect transistors (VTFETs) is provided. The method includes forming a bottom spacer on a first device region associated with a first VTFET and a second device region associated with a second VTFET, forming a liner on the bottom spacer, on a first fin structure including silicon germanium (SiGe) formed in the first device region and on a second fin structure including SiGe formed in the second device region, and forming crystalline Ge having a hexagonal structure from the SiGe by employing a Ge condensation process to orient a (111) direction of the crystalline Ge in a direction of charge flow for a VTFET.

Abstract: An optoelectronic device including: a first, p-doped semiconductor layer and a second, n-doped semiconductor layer which are superposed and form a p-n junction; a first electrode electrically connected to the first semiconductor layer and forming an anode of the device; a gate positioned against at least one lateral flank of the first semiconductor layer; a second electrode, positioned against a lateral flank of the second semiconductor layer, electrically connected to the second semiconductor layer and electrically isolated from the first semiconductor layer; and in which a portion of the second electrode is positioned against the gate such that the second electrode is electrically connected to the gate and forms both a gate electrode and a cathode of the device.

Abstract: A memory device includes: a memory cell array; a data selector configured to receive data from the memory cell array, and to output the received data as first sub-data and second sub-data; a cyclic redundancy check (CRC) generator configured to generate first CRC values corresponding to the first sub-data, and to generate second CRC values corresponding to the second sub-data; a CRC selector configured to determine an order of the first CRC values and the second CRC values, and to output one of the first CRC values and one of the second CRC values according to the determined order; and a transmitter configured to receive the first CRC values and the second CRC values according to the determined order, and to transmit CRC values of the data by a multilevel signaling method.

Abstract: A method of forming a bit line gate structure of a dynamic random access memory (DRAM) includes the following steps. A polysilicon layer is formed on a substrate. A sacrificial layer is formed on the polysilicon layer. An implantation process is performed on the sacrificial layer and the polysilicon layer. The sacrificial layer is removed. A metal stack is formed on the polysilicon layer. The present invention also provides another method of forming a bit line gate structure of a dynamic random access memory (DRAM) including the following steps. A polysilicon layer is formed on a substrate. A plasma doping process is performed on a surface of the polysilicon layer. A metal stack is formed on the surface of the polysilicon layer.

Abstract: A semiconductor device and a method for manufacturing the semiconductor device are provided. The semiconductor device uses an aluminum alloy, rather than aluminum, for a metal gate. Therefore, the surface of the high-k metal gate after the CMP is aluminum alloy rather than pure aluminum, which can greatly reduce defects, such as corrosion, pits and damage, in the metal gate and improve reliability of the semiconductor device.

Abstract: Forming a photoresist on a region other than a region on a trench gate electrode for a mask, a third gate insulating film on the trench gate electrode is etched and removed. After that, a non-doped polycrystalline silicon layer is formed on second and third gate insulating films and also on the trench gate electrode, and, N-type and P-type high concentration impurities are introduced by an ion implantation with the use of separate masks on the polycrystalline silicon layer of NMOS transistors and PMOS transistors with a low breakdown voltage and a high breakdown voltage. Then, a second gate electrode is formed by anisotropic etching. With the steps as described above, a first gate electrode inside the trench and the second gate electrode to be used in the lateral MOS transistor are laminated, to thereby reduce fluctuations due to the etching.

Abstract: Embodiments of the invention relate to field effect transistors. The field effect transistor includes a gate electrode for providing a gate field, a first electrode including a conductive material having a low carrier density and a low density of electronic states, a second electrode, and a semiconductor. Contact barrier modulation includes barrier height lowering of a Schottky contact between the first electrode and the semiconductor. In some embodiments of the invention, a vertical field effect transistor employs an electrode comprising a conductive material with a low density of states such that the transistors contact barrier modulation comprises barrier height lowering of the Schottky contact between the electrode with a low density of states and the adjacent semiconductor by a Fermi level shift.

Abstract: A semiconductor device includes a first insulating film formed between a gate electrode and a first flat semiconductor layer, and a sidewall-shaped second insulating film formed to surround an upper sidewall of a first columnar silicon layer while contacting an upper surface of the gate electrode and to surround a sidewall of the gate electrode and the first insulating film. The semiconductor device further includes a metal-semiconductor compound formed on each of an upper surface of a first semiconductor layer of the second conductive type formed in the entirety or the upper portion of the first flat semiconductor layer, and an upper surface of the second semiconductor layer of the second conductive type formed in the upper portion of the first columnar semiconductor layer.

Abstract: It is an object to provide an SGT production method capable of obtaining a structure for reducing a resistance of a gate, a desired gate length, desired source and drain configurations and a desired diameter of a pillar-shaped semiconductor.

Abstract: In a power IC device, a surface layer channel CMOS transistor and a trench power MOS transistor are formed on the same chip. In one embodiment, a source region of the trench power MOS transistor is arranged at the same level as a gate electrode of the surface layer channel CMOS transistor. Thus, the power IC device and a method for manufacturing the power IC device are provided for reducing manufacturing cost in the case of forming the trench power MOS transistor and the surface layer channel CMOS transistor on the same chip.

Abstract: A method of manufacturing a nonvolatile memory device having a laminated structure in which a first magnetic material layer, a tunnel insulator film, and a second magnetic material layer are sequentially laminated, in which information is stored when an electric resistance value changes depending on a magnetization reversal state is disclosed. The method includes the steps of: sequentially forming the first magnetic material layer, the tunnel insulator film, and the second magnetic material layer; forming a mask layer on the second magnetic material layer; oxidizing a part uncovered by the mask layer of the second magnetic material layer; and reducing the oxidized part of the second magnetic material layer.

Abstract: A method and structures are provided for implementing metal via gate node high performance stacked vertical transistors in a back end of line (BEOL) on a semiconductor System on Chip (SoC). The high performance stacked vertical transistors include a pair of stacked vertical field effect transistors (FETs) formed by polycrystalline depositions in a stack between planes of a respective global signal routing wire. A channel length of each of the stacked vertical FETs is delineated by the polycrystalline depositions with sequential source deposition, channel deposition and drain deposition; and a wire via defines the gate node.

Abstract: In contrast to a conventional planar CMOS technique in design and fabrication for a field-effect transistor (FET), the present invention provides an SGT CMOS device formed on a conventional substrate using various crystal planes in association with a channel type and a pillar shape of an FET, without a need for a complicated device fabrication process. Further, differently from a design technique of changing a surface orientation in each planar FET, the present invention is designed to change a surface orientation in each SGT to achieve improvement in carrier mobility. Thus, a plurality of SGTs having various crystal planes can be formed on a common substrate to achieve a plurality of different carrier mobilities so as to obtain desired performance.

Abstract: Disclosed herein is a semiconductor device having a vertical MOS transistor having a channel of a first conductivity type and formed by burying a gate electrode in a semiconductor substrate, a planar MOS transistor having a channel of the first conductivity and having a gate electrode formed on the semiconductor substrate, and a planar MOS transistor having a channel of a second conductivity and having a gate electrode formed on the semiconductor substrate, the semiconductor device, including other circuit element(s), other than a transistor, formed either below or above the vertical MOS transistor having the channel of the first conductivity type.

Abstract: It is an object to provide an SGT production method capable of obtaining a structure for reducing a resistance of a gate, a desired gate length, desired source and drain configurations and a desired diameter of a pillar-shaped semiconductor.

Abstract: A semiconductor device and a method for manufacturing the device are disclosed in which the semiconductor device includes ohmic contacts on different planes and the method for manufacturing the device includes etching a semiconductor stack of different conductivity semiconductor layers in successive steps to create a first opening of a first width in a first semiconductor layer to expose another semiconductor layer, and then a second opening of a narrower width in the another layer, whereby a portion of the another layer remains exposed for receiving an ohmic contact.

Abstract: A process for manufacturing a MOS device includes forming a semiconductor layer having a first type of conductivity; forming an insulated gate structure having an electrode region (25), above the semiconductor layer (23); forming body regions having a second type of conductivity, within the semiconductor layer, laterally and partially underneath the insulated gate structure; forming source regions having the first type of conductivity, within the body regions; and forming a first enrichment region, in a surface portion of the semiconductor layer underneath the insulated gate structure. The first enrichment region has the first type of conductivity and is set at a distance from the body regions. In order to form the first enrichment region, a first enrichment window is defined within the insulated gate structure, and first dopant species of the first type of conductivity are introduced through the first enrichment window and in a way self-aligned thereto.

Abstract: There is provided a semiconductor device formed of a highly integrated high-speed CMOS inverter coupling circuit using SGTs provided on at least two stages. A semiconductor device according to the present invention is formed of a CMOS inverter coupling circuit in which n (n is two or above) CMOS inverters are coupled with each other, each of the n inverters has: a pMOS SGT; an nMOS SGT, an input terminal arranged so as to connect a gate of the pMOS SGT with a gate of the nMOS SGT; an output terminal arranged to connect a drain diffusion layer of the pMOS SGT with a drain diffusion layer of the nMOS SGT in an island-shaped semiconductor lower layer; a pMOS SGT power supply wiring line arranged on a source diffusion layer of the pMOS SGT; and an nMOS SGT power supply wiring line arranged on a source diffusion layer of the NMOS SGT, and an n?1th output terminal is connected with an nth input terminal.

Abstract: An insulated gate silicon carbide semiconductor device is provided having small on-resistance in a structure obtained by combining the SIT and MOSFET structures having normally-off operation. The device includes an n? semiconductor layer on an SiC n+ substrate, a p-type base region and highly doped p-region both buried in the layer, a trench from the semiconductor layer surface to the p-base region, an n+ first source region in the surface of a p-type base region at the bottom of the trench, a p-type channel region in the surface of the sidewall of the trench, one end of which contacts the first source region, a gate electrode contacting the trench-side surface of the channel region via a gate insulating film, and a source electrode contacting the trench-side surface of the gate electrode via an interlayer insulating film and contacting the exposed first source region and p-base region at the bottom of the trench.

Abstract: Methods are provided for fabricating Bulk FinFET devices having deep trench isolation. One or more deep isolation trenches are formed in a bulk silicon wafer. Mandrel-forming material is deposited overlying the bulk silicon wafer and dielectric pad layer thereon and simultaneously into the trench(es) as filler material. Mandrels are formed, overetching thereof creating a recess at the trench upper end. A conformal sidewall spacer material from which sidewall spacers are fabricated is deposited overlying the mandrels and into the recess forming a spacer overlying the filler material in the trench(es). Mandrels are removed using the spacer as an etch stop. Fin structures are formed from the bulk silicon wafer using the sidewall spacers as an etch mask. The mandrel-forming material is amorphous and/or polycrystalline silicon.

Abstract: In a replacement gate approach, a top area of a gate opening has a superior cross-sectional shape which is accomplished on the basis of a plasma assisted etch process or an ion sputter process. During the process, a sacrificial fill material protects sensitive materials, such as a high-k dielectric material and a corresponding cap material. Consequently, the subsequent deposition of a work function adjusting material layer may not result in a surface topography which may result in a non-reliable filling-in of the electrode metal. In some illustrative embodiments, the sacrificial fill material may also be used as a deposition mask for avoiding the deposition of the work function adjusting metal in certain gate openings in which a different type of work function adjusting species is required.

Abstract: A method for manufacturing a CMOS transistor includes preparing a silicon substrate provided with a first buried layer, a second buried layer and a body, vertically forming device-isolation films inside the body, forming a first-type well inside the body arranged on the first buried layer, and vertically forming a first source and drain region inside the first-type well, forming a second-type well inside the body arranged on the second buried layer, and vertically forming a second source and drain region inside the second-type well, and vertically forming a recessed gate between the first-type well and the second-type well.

Abstract: A MOS transistor having an increased gate-drain capacitance is described. One embodiment provides a drift zone of a first conduction type. At least one transistor cell has a body zone, a source zone separated from the drift zone by the body zone, and a gate electrode, which is arranged adjacent to the body zone and which is dielectrically insulated from the body zone by a gate dielectric. At least one compensation zone of the first conduction type is arranged in the drift zone. At least one feedback electrode is arranged at a distance from the body zone, which is dielectrically insulated from the drift zone by a feedback dielectric and which is electrically conductively connected to the gate electrode.

Abstract: A semiconductor device and methods for its fabrication are provided. The semiconductor device comprises a trench formed in the semiconductor substrate and bounded by a trench wall extending from the semiconductor surface to a trench bottom. A drain region and a source region, spaced apart along the length of the trench, are formed along the trench wall, each extending from the surface toward the bottom. A channel region is formed in the substrate along the trench wall between the drain region and the source region and extending along the length of the trench parallel to the substrate surface. A gate insulator and a gate electrode are formed overlying the channel.

Abstract: A method for forming a vertical channel transistor in a semiconductor device includes providing a substrate, forming pillar patterns extending perpendicular from the upper surface of the substrate, forming a spin on carbon (SOC) layer in a gap region between the pillar patterns, forming photoresist patterns above a resultant structure where the SOC layer is filled to expose a region for an isolation trench, etching the SOC layer between the photoresist pattern barriers to expose the region for the isolation trench, and etching the exposed structure to a certain depth forming the isolation trench.

Abstract: Disclosed herein is a semiconductor device having a vertical MOS transistor having a channel of a first conductivity type and formed by burying a gate electrode in a semiconductor substrate, a planar MOS transistor having a channel of the first conductivity and having a gate electrode formed on the semiconductor substrate, and a planar MOS transistor having a channel of a second conductivity and having a gate electrode formed on the semiconductor substrate, the semiconductor device, including other circuit element(s), other than a transistor, formed either below or above the vertical MOS transistor having the channel of the first conductivity type.

Abstract: A manufacturing method is provided for a power semiconductor device that enables reducing its on-state voltage and power loss. The semiconductor device includes a set of L-shaped trench gates 3 each formed, from the top-side surface of a p base layer 2, perpendicularly with respect to a first main surface of an n? layer 1, to reach into a location of the n? layer 1. At the lower ends of each of the trench gates 3, bottom portions 3d are provided to unilaterally extend a predetermined length in one direction parallel to the first main surface of the n? layer 1. In addition, the extending end of one of the bottom portions 3d opposes that of the other bottom portion, on the extending side of the bottom portions 3d, and the interspace between each pair of adjacent bottom portions 3d is set narrower than any other interspace between the trench-gate parts that are perpendicularly formed with respect to the first main surface of the n? layer 1.

Abstract: The invention includes methods of forming layers comprising epitaxial silicon. In one implementation, an opening is formed within a first material received over a monocrystalline material. Opposing walls, of a second material, are formed within the opening which are laterally displaced inwardly of the opposing sidewalls, a space being received between the opposing walls and the opposing sidewalls, with monocrystalline material being exposed between the opposing walls within the opening. A silicon-comprising layer is epitaxially grown from the exposed monocrystalline material within the second material-lined opening. Other aspects and implementations are contemplated.

Abstract: Disclosed is a semiconductor device production method, which comprises the steps of: forming a pillar-shaped first-conductive-type semiconductor layer on a planar semiconductor layer; forming a second-conductive-type semiconductor layer in a portion of the planar semiconductor layer underneath the pillar-shaped first-conductive-type semiconductor layer; forming a gate dielectric film and a gate electrode having a laminated structure of a metal film and an amorphous silicon or polysilicon film, around the pillar-shaped first-conductive-type semiconductor layer; forming a sidewall-shaped dielectric film on an upper region of a sidewall of the pillar-shaped first-conductive-type semiconductor layer and in contact with a top of the gate electrode; forming first and second sidewall-shaped dielectric films on a sidewall of the gate electrode; forming a second-conductive-type semiconductor layer in an upper portion of the pillar-shaped first-conductive-type semiconductor layer; forming a metal-semiconductor compound

Abstract: A method of fabricating a vertical channel transistor for a semiconductor device includes forming, on a substrate, a plurality of active pillars each having a gate electrode formed on and surrounding a lower portion thereof; forming a first insulation layer over the active pillars to fill a gap region between the active pillars; partially removing the first insulation layer to exposes a circumferential surface of the gate electrode in all directions, without exposing the substrate in the gap region between the active pillars; forming a conductive layer on the remaining first insulation layer to fill the gap region between the active pillars; and patterning the conductive layer to form a word line that surrounds and contacts the circumferential surface of the gate electrode in all directions.

Abstract: There are provided a semiconductor device having a vertical transistor and a method of fabricating the same. The method includes preparing a semiconductor substrate having a cell region and a peripheral circuit region. Island-shaped vertical gate structures two-dimensionally aligned along a row direction and a column direction are formed on the substrate of the cell region. Each of the vertical gate structures includes a semiconductor pillar and a gate electrode surrounding a center portion of the semiconductor pillar. A bit line separation trench is formed inside the semiconductor substrate below a gap region between the vertical gate structures, and a peripheral circuit trench confining a peripheral circuit active region is formed inside the semiconductor substrate of the peripheral circuit region. The bit line separation trench is formed in parallel with the column direction of the vertical gate structures.

Abstract: The invention provides a method of fabricating an extremely short-length dual-gate FET, using conventional semi-conductor processing techniques, with extremely small and reproducible fins with a pitch and a width that are both smaller than can be obtained with photolithographic techniques. On a protrusion (2) on a substrate (1), a first layer (3) and a second layer (4) are formed, after which the top surface of the protrusion (2) is exposed. A portion of the first layer (3) is selectively removed relative to the protrusion (2) and the second layer (4), thereby creating a fin (6) and a trench (5). Also a method is presented to form a plurality of fins (6) and trenches (5). The dual-gate FET is created by forming a gate electrode (7) in the trench(es) (5) and a source and drain region. Further a method is presented to fabricate an extremely short-length asymmetric dual-gate FET with two gate electrodes that can be biased separately.

Abstract: A method of fabricating a vertical CMOS image sensor is disclosed, to improve the integration with the decrease in size of pixel by minimizing the lateral diffusion, in which phosphorous and arsenic ions are implanted while controlling the dose and energy, the method including forming a first photodiode in a semiconductor substrate; forming a first epitaxial layer on the semiconductor substrate; forming a first plug by sequentially implanting first and second ions in the first epitaxial layer; forming a second photodiode in the first epitaxial layer; forming a second epitaxial layer in the first epitaxial layer; forming an isolation area in the second epitaxial layer; and forming a third photodiode and a second plug in the second epitaxial layer.

Abstract: A castellated-gate MOSFET I/O device capable of fully depleted operation is disclosed. The device includes a semiconductor substrate region having an upper portion with a top surface and a lower portion with a bottom surface. A source region and a drain region are formed in the semiconductor substrate region, and a channel-forming region is also disposed therein between the source and drain regions. Trench isolation insulator islands, having upper and lower surfaces, surround the source and drain regions as well as the channel-forming region. The channel-forming region includes a plurality of thin, spaced, vertically-orientated conductive channel elements that span longitudinally along the device between the source and drain regions. A gate structure is provided in the form of a plurality of spaced, castellated gate elements interposed between the channel elements, and a top gate member interconnects the gate elements at their upper vertical ends to cover the channel elements.

Abstract: A manufacturing method of a semiconductor device includes: forming multiple trenches on a semiconductor substrate; forming a second conductive type semiconductor film in each trench to provide a first column with the substrate between two trenches and a second column with the second conductive type semiconductor film in the trench, the first and second columns alternately repeated along with a predetermined direction; thinning a second side of the substrate; and increasing an impurity concentration in a thinned second side so that a first conductive type layer is provided. The impurity concentration of the first conductive type layer is higher than the first column. The first column provides a drift layer so that a vertical type first-conductive-type channel transistor is formed.

Abstract: The present invention provides a semiconductor device (20) comprising a trench (5) formed in a semiconductor substrate formed of a stack (4) of layers (1,2,3), a layer (6) of a first, grown dielectric material covering sidewalls and bottom of the trench (5), the layer (6) including one or more notches (13) at the bottom of the trench (5) and one or more spacers (14) formed of a second, deposited dielectric material to fill the one or more notches (13) in the layer (6) formed of the first, grown dielectric material. The semiconductor device (20) according to the present invention shows improved breakdown voltage and on-resistance. The present invention furthermore provides a method for the manufacturing of such semiconductor devices (20).

Abstract: In a trench MOSFET, the lower portion of the trench contains a buried source electrode, which is insulated from the epitaxial layer and semiconductor substrate but in electrical contact with the source region. When the MOSFET is in an “off” condition, the bias of the buried source electrode causes the “drift” region of the mesa to become depleted, enhancing the ability of the MOSFET to block current. The doping concentration of the drift region can therefore be increased, reducing the on-resistance of the MOSFET. The buried source electrode also reduces the gate-to-drain capacitance of the MOSFET, improving the ability of the MOSFET to operate at high frequencies. The substrate may advantageously include a plurality of annular trenches separated by annular mesas and a gate metal layer that extends outward from a central region in a plurality of gate metal legs separated by source metal regions.

Abstract: A method for growing planar, semi-polar nitride film on a miscut spinel substrate, in which a large area of the planar, semi-polar nitride film is parallel to the substrate's surface. The planar films and substrates are: (1) {10 11} gallium nitride (GaN) grown on a {100} spinel substrate miscut in specific directions, (2) {10 13} gallium nitride (GaN) grown on a {110} spinel substrate, (3) {11 22} gallium nitride (GaN) grown on a {1 100} sapphire substrate, and (4) {10 13} gallium nitride (GaN) grown on a {1 100} sapphire substrate.

Abstract: A piezoelectric micro electro-mechanical system switch (MEMS), an array of piezoelectric MEMS switches, and a method of fabricating the switch, which are capable of improving low voltage and switching characteristics while securing high signal isolation, are provided. The piezoelectric MEMS switch includes a semiconductor substrate including a groove, a support formed over the semiconductor substrate and the groove. An actuator including a piezoelectric layer is formed on the support. A switching member is formed on the support on one side of the actuator, wherein upward movement of the switching member changes by a deformation of the piezoelectric layer of the actuator. Radio frequency (RF) transfer lines are arranged at a predetermined distance on the switching member and are separated by a predetermined interval from each other. The actuator is formed to have at least two cantilevers each having one end such that the ends are connected to each other.

Abstract: A manufacturing method of a semiconductor device includes: forming multiple trenches on a semiconductor substrate; forming a second conductive type semiconductor film in each trench to provide a first column with the substrate between two trenches and a second column with the second conductive type semiconductor film in the trench, the first and second columns alternately repeated along with a predetermined direction; thinning a second side of the substrate; and increasing an impurity concentration in a thinned second side so that a first conductive type layer is provided. The impurity concentration of the first conductive type layer is higher than the first column. The first column provides a drift layer so that a vertical type first-conductive-type channel transistor is formed.

Abstract: In a power IC device, a surface layer channel CMOS transistor and a trench power MOS transistor are formed on the same chip. In one embodiment, a source region of the trench power MOS transistor is arranged at the same level as a gate electrode of the surface layer channel CMOS transistor. Thus, the power IC device and a method for manufacturing the power IC device are provided for reducing manufacturing cost in the case of forming the trench power MOS transistor and the surface layer channel CMOS transistor on the same chip.

Abstract: A transistor assembly with semiconductor material vertically introduced into micro holes (4) in a pliable a film laminate consisting of two plastic films (1, 3) with a metal layer (2) located therebetween. Said semiconductor material is provided with contacts (6, 7) by metalizing the top side and bottom side of the film laminate. The assembly is very strong by virtue of the fact that the film can be bent and stretched.

Abstract: A multi-fin field effect transistor includes a substrate, an oxide layer, a conductive layer, a gate oxide layer, and a doped region is provided. The substrate is surrounded by a trench, and there are at least two fin-type silicon layers formed in the substrate in a region prepared to form a gate thereon. The oxide layer is disposed in the trench and the top surface of the oxide layer is lower than that of the fin-type silicon layers. The conductive layer is disposed in the region prepared to form a gate. The top surface of the conductive layer is higher than that of the fin-type silicon layers. The gate oxide layer is disposed between the conductive layer and the fin-type silicon layers and disposed between the conductive layer and the substrate. The doped region is disposed in the substrate on both sides of the conductive layer.

Abstract: A complementary metal oxide semiconductor (CMOS) structure includes a semiconductor substrate having first mesa having a first ratio of channel effective horizontal surface area to channel effective vertical surface area. The CMOS structure also includes a second mesa having a second ratio of the same surface areas that is greater than the first ratio. A first device having a first polarity uses the first mesa as a channel and benefits from the enhanced vertical crystallographic orientation. A second device having a second polarity different from the first polarity uses the second mesa as a channel and benefits from the enhanced horizontal crystallographic orientation.

Abstract: The invention provides a method of fabricating an extremely short-length dual-gate FET, using conventional semi-conductor processing techniques, with extremely small and reproducible fins with a pitch and a width that are both smaller than can be obtained with photolithographic techniques. On a protrusion (2) on a substrate (1), a first layer (3) and a second layer (4) are formed, after which the top surface of the protrusion (2) is exposed. A portion of the first layer (3) is selectively removed relative to the protrusion (2) and the second layer (4), thereby creating a fin (6) and a trench (5). Also a method is presented to form a plurality of fins (6) and trenches (5). The dual-gate FET is created by forming a gate electrode (7) in the trench(es) (5) and a source and drain region. Further a method is presented to fabricate an extremely short-length asymmetric dual-gate FET with two gate electrodes that can be biased separately.

Abstract: A semiconductor device 100 includes an element-forming region having gate electrode 108 formed therein, and a circumferential region formed in the outer circumference of the element-forming region and having an element-isolating region 118 formed therein. On the main surface of the semiconductor substrate 101, there is formed a parallel pn layer having an N-type drift region 104 and P-type column regions 106 alternately arranged therein. In the circumferential region, there is formed a field electrode 120, but the field electrode 120 is not formed on the P-type column regions 106. The P-type column regions 106 in the circumferential region are formed with a depth larger than or equal to that of the P-type column regions 106 in the element-forming region.

Abstract: In one implementation, field oxide is grown within bulk semiconductive material in a first circuitry area and not over immediately adjacent bulk semiconductive material in a second circuitry area. The field oxide is etched from the first circuitry area. After the etching, a circuit component is formed in the first circuitry area and a circuit component is formed in the second circuitry area. Dielectric material is formed over the first and second circuitry areas. The dielectric material comprises a conductive contact extending outwardly from the circuit component in the first circuitry area. The dielectric material has a first outermost surface. A portion of the dielectric material and a portion of the conductive contact are removed to form a second outermost surface of the dielectric material which has greater degree of planarity than did the first outermost surface. Other aspects are contemplated.

Abstract: The invention is related to a DRAM cell arrangement with vertical MOS transistors. Channel regions arranged along one of the columns of a memory cell matrix are parts of a rib which is surrounded by a gate dielectric layer. Gate electrodes of the MOS transistors belonging to one row are parts of a strip-like word line, so that at each crossing point of the memory cell matrix there is a vertical dual-gate MOS transistor with gate electrodes of the associated word line formed in the trenches on both sides of the associated rib.