Abstract: A method for producing a semiconductor component is provided. The method includes providing a semiconductor body with a first surface and a second surface opposite to the first surface, etching an insulation trench from the first surface partially into the semiconductor body, forming a first insulation layer on one or more sidewalls of the insulation trench, processing the second surface by at least one of grinding, polishing and a CMP-process to expose the first insulation layer, and depositing on the processed second surface a second insulation layer which extends to the first insulation layer.

Abstract: A compound semiconductor device includes a compound semiconductor layer, a gate electrode disposed above the compound semiconductor layer, and a gate insulation film. The gate insulation film is interposed between the compound semiconductor layer and the gate electrode. The gate insulation film contains a fluorine compound at least in the vicinity of the interface with the compound semiconductor layer.

Abstract: A vertical semiconductor device includes a first active pillar vertically protruded from a semiconductor substrate; a first vertical gate connected to at least one side of the first active pillar and formed along a direction that crosses a buried bit line; and a first body line connected to at least one side of the first active pillar which is not connected to the first vertical gate.

Abstract: In an MIS structure a field plate electrode is incorporated below a buried gate electrode by using an insulating oxide layer, which is formed concurrently with the gate dielectric layer. In order to obtain superior dynamic behavior and enhanced dielectric strength the oxidation behavior of the field plate electrode is modified, for instance by incorporating a desired high concentration of arsenic.

Abstract: A method for producing a semiconductor component includes providing a semiconductor body with a first surface and a second surface opposite the first surface, forming an insulation trench which extends into the semiconductor body from the first surface and which in a horizontal plane of the semiconductor body has a geometry such that the insulation trench defines a via region of the semiconductor body, forming a first insulation layer on one or more sidewalls of the insulation trench, removing semiconductor material of the semiconductor body from the second surface to expose at least parts of the first insulation layer, to remove at least parts of the first insulation layer, or to leave at least partially a semiconductor layer with a thickness of less than 1 ?m between the first insulation layer and the second surface, and forming first and second contact electrodes on the via region.

Abstract: The power device with low parasitic transistor comprises a recessed transistor and a heavily doped region at a side of a source region of the recessed transistor. The conductive type of the heavily doped region is different from that of the source region. In addition, a contact plug contacts the heavily doped region and connects the heavily doped region electrically. A source wire covers and contacts the source region and the contact plug to make the source region and the heavily doped region have the same electrical potential.

Abstract: A vertical semiconductor device includes a first pillar and a second pillar, a first bit line contact formed at a lower portion of a first sidewall of the first pillar, a second bit line contact formed at a lower portion of a second sidewall of the second pillar which face the first sidewall of the first pillar, a bit line commonly connected to the first bit line contact and the second bit line contact, and a gate formed at both sides of the first pillar and the second pillar to be crossed with the bit line.

Abstract: A memory array with staggered local data/bit lines extending generally in a first direction formed in an upper surface of a substrate and memory cell access transistors extending generally upward and aligned generally atop a corresponding local data/bit line. Selected columns of the memory cell access transistors are sacrificed to define local data/bit access transistors which are interconnected with overlying low resistance global data/bit lines. The global data/bit lines provide selectable low resistance paths between memory cells and sense amplifiers. The sacrificed memory cell access transistors and staggered local data/bit lines provide increased footprints for sense amplifiers to facilitate increased circuit integration.

Abstract: A field effect transistor (FET) includes a trench extending into a semiconductor region. A conductive electrode is disposed in the trench, and the conductive electrode is insulated from the semiconductor region by a dielectric layer. The conductive electrode includes a conductive liner lining the dielectric layer along opposite sidewalls of the trench. The conductive liner has tapered edges such that a thickness of the conductive liner gradually increases from a top surface of the conductive electrode to a point in lower half of the conductive electrode. The conductive electrode further includes a conductive fill material sandwiched by the conductive liner. The FET further includes a drift region of a first conductivity type in the semiconductor region, and a body region of a second conductivity type extending over the drift region. Source regions of the first conductivity type extend in the body region adjacent the trench.

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, above the semiconductor layer; 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: A semiconductor element 100 including an MISFET according to the present invention is characterized by having diode characteristics in a reverse direction through an epitaxial channel layer 50. The semiconductor element 100 includes a semiconductor layer 20 of a first conductivity type, a body region 30 of a second conductivity type, source and drain regions 40 and 75 of the first conductivity type, an epitaxial channel layer 50 in contact with the body region, source and drain electrodes 45 and 70, a gate insulating film 60, and a gate electrode 65. If the voltage applied to the gate electrode of the MISFET is smaller than a threshold voltage, the semiconductor element 100 functions as a diode in which current flows from the source electrode 45 to the drain electrode 70 through the epitaxial channel layer 50. The absolute value of the turn-on voltage of this diode is smaller than that of the turn-on voltage of a body diode that is formed of the body region and the first silicon carbide semiconductor layer.

Abstract: A first AlGaN layer formed over a substrate, a second AlGaN layer formed over the first AlGaN layer, an electron transit layer formed over the second AlGaN layer, and an electron supply layer formed over the electron transit layer are provided. A relationship of “0?x1<x2?1” is found when a composition of the first AlGaN layer is represented by Alx1Ga1-x1N, and a composition of the second AlGaN layer is represented by Alx2Ga1-x2N. Negative charges exist at an upper surface of the AlGaN layer more than positive charges existing at a lower surface of the AlGaN layer.

Abstract: On a surface of a compound semiconductor layer including inner wall surfaces of an electrode trench, an etching residue 12a and an altered substance 12b which are produced due to dry etching for forming the electrode trench are removed, and a compound semiconductor is terminated with fluorine. Gate metal is buried in the electrode trench via a gate insulating film, or the gate metal is directly buried in the electrode trench, whereby a gate electrode is formed.

Abstract: A nonvolatile memory device includes a substrate, a structure including a stack of alternately disposed layers of conductive and insulation materials disposed on the substrate, a plurality of pillars extending through the structure in a direction perpendicular to the substrate and into contact with the substrate, and information storage films interposed between the layers of conductive material and the pillars. In one embodiment, upper portions of the pillars located at the same level as an upper layer of the conductive material have structures that are different from lower portions of the pillars. In another embodiment, or in addition, upper string selection transistors constituted by portions of the pillars at the level of an upper layer of the conductive material are programmed differently from lower string selection transistors.

Abstract: A vertical structure non-volatile memory device includes a channel region that vertically extends on a substrate. A memory cell string vertically extends on the substrate along a first wall of the channel regions, and includes at least one selection transistor and at least one memory cell. An impurity providing layer is disposed on a second wall of the channel region and includes impurities.

Abstract: A voltage converter can include an output circuit having a vertical high-side device and a vertical low-side device which can be formed on a single die (i.e. a “PowerDie”). The high side device can be a PMOS transistor, while the low side device can be an NMOS transistor. The source of the PMOS transistor and the source of the NMOS transistor can be formed from the same metal structure, with the source of the high side device electrically connected to VIN and the source of the low side device electrically connected to ground. A drain of the high side PMOS transistor can be electrically shorted to the drain of the low side NMOS transistor during device operation using a metal layer which is interposed between the transistors and a semiconductor substrate.

Abstract: Provided are semiconductor devices and methods of manufacturing the same. The semiconductor device may include a substrate provided with a transistor, an insulating layer disposed on the substrate, the insulating layer including a contact hole exposing a portion of the transistor, a spacer disposed on an inner sidewall of the contact hole, and a contact plug disposed in the contact hole. Here, a space defined by the spacer may increase in width from a bottom side thereof to a top side thereof.

Abstract: A method of forming an integrated circuit structure includes providing a semiconductor substrate; and forming a first and a second MOS device. The first MOS device includes a first active region in the semiconductor substrate; and a first gate over the first active region. The second MOS device includes a second active region in the semiconductor substrate; and a second gate over the second active region. The method further include forming a dielectric region between the first and the second active regions, wherein the dielectric region has an inherent stress; and implanting the dielectric region to form a stress-released region in the dielectric region, wherein source and drain regions of the first and the second MOS devices are not implanted during the step of implanting.

Abstract: A semiconductor device includes a substrate having a plurality of horizontal channel transistors formed thereon, an insulation layer structure on the substrate and covering the horizontal transistors, and a plurality of vertical channel transistors on the insulation layer structure.

Abstract: A semiconductor component having a semiconductor body is disclosed. In one embodiment, the semiconductor component includes a drift zone of a first conductivity type, a drift control zone composed of a semiconductor material which is arranged adjacent to the drift zone at least in places, a dielectric which is arranged between the drift zone and the drift control zone at least in places. A quotient of the net dopant charge of the drift control zone, in an area adjacent to the accumulation dielectric and the drift zone, divided by the area of the dielectric arranged between the drift control zone and the drift zone is less than the breakdown charge of the semiconductor material in the drift control zone.

Abstract: A semiconductor device includes a semiconductor substrate having a first gate groove having first and second side walls facing to each other. A first gate insulating film covers the first and second side walls. A first gate electrode is disposed on the first gate insulating film and in a lower portion of the first gate groove. A first burying insulating film buries the first gate groove and covers the first gate electrode. A first diffusion region is adjacent to a first upper portion of the first gate insulating film. The first upper portion is positioned on an upper portion of the first side wall of the first gate groove. A second diffusion region is in contact with an upper portion of the second side wall of the first gate groove.

Abstract: An oxide termination semiconductor device may comprise a plurality of gate trenches, a gate runner, and an insulator termination trench. The gate trenches are located in an active region. Each gate trench includes a conductive gate electrode. The insulator termination trench is located in a termination region that surrounds the active region. The insulator termination trench is filled with an insulator material to form an insulator termination for the semiconductor device. The device can be made using a three-mask or four-mask process.

Abstract: The semiconductor device according to the present invention includes: a semiconductor layer of a first conductivity type made of SiC having an Si surface; a gate trench dug down from the surface of the semiconductor layer; a gate insulating film formed on a bottom surface and a side surface of the gate trench so that the ratio of the thickness of a portion located on the bottom surface to the thickness of a portion located on the side surface is 0.3 to 1.0; and a gate electrode embedded in the gate trench through the gate insulating film.

Abstract: It is intended to provide a semiconductor device including a MOS transistor, comprising: a semiconductor pillar; one of a drain region and a source region formed in contact with a lower part of the semiconductor pillar; a first gate formed around a sidewall of the semiconductor pillar through a first dielectric film therebetween; and an epitaxial semiconductor layer formed on a top surface of the semiconductor pillar, wherein the other of the source region and the drain region is formed so as to be at least partially in the epitaxial semiconductor layer, and wherein: the other of the source region and the drain region has a top surface having an area greater than that of the top surface of the semiconductor pillar.

Abstract: In an embodiment, set forth by way of example and not limitation, a MOSFET power chip includes a first vertical MOSFET and a second vertical MOSFET. The first vertical MOSFET includes a semiconductor body having a first surface defining a source and a second surface defining a drain and a gate structure formed in the semiconductor body near the second surface. A via is formed within the semiconductor body and is substantially perpendicular to the first surface and the second surface. The via has a first end electrically coupled to the first surface and a second end electrically coupled to the gate structure. The second vertical MOSFET includes a semiconductor body having a first surface defining a source, a second surface defining a drain and a gate structure formed in the semiconductor body near the first surface.

Abstract: A method for producing a power field effect transistor (FET) device having a low series resistance between the drain and source when switched on has the steps of: forming a vertical power FET in a semiconductor die; and back-grinding the semiconductor die to a thickness of less than or equal to about 100 ?m (4 mils) or less.

Abstract: The present invention provides a method for forming a channel material, comprising: forming a substrate; forming an MOS device with a dummy gate stack on the substrate; removing the dummy gate stack; forming a channel trench at the channel located under the dummy gate stack; filling the channel trench with the channel material; and forming a gate stack. According to the embodiments of the present invention, the channel material is formed by a replacement gate process after the high temperature process, such as a high temperature annealing, thereby any negative influence on the formed channel material due to the high temperature process may be effectively avoided.

Abstract: A metal source power transistor device and method of manufacture is provided, wherein the metal source power transistor having a source which is comprised of metal and which forms a Schottky barrier with the body region and channel region of the transistor. The metal source power transistor is unconditionally immune from parasitic bipolar action and, therefore, the effects of snap-back and latch-up, without the need for a body contact. The ability to allow the body to float in the metal source power transistor reduces the process complexity and allows for more compact device layout.

Abstract: A semiconductor apparatus that has a first parallel pn-layer formed between an active region and an n+-drain region. A peripheral region is provided with a second parallel pn-layer, which has a repetition pitch narrower than the repetition pitch of the first parallel pn-layer. An n?-surface region is formed between the second parallel pn-layer and a first main surface. On the first main surface side of the n?-surface region, a plurality of p-guard ring regions are formed to be separated from each other. A field plate electrode is connected electrically to the outermost p-guard ring region among the p-guard ring regions. A channel stopper electrode is connected electrically to an outermost peripheral p-region of the peripheral region.

Abstract: An integrated circuit includes a semiconductor carrier including a first side and a second side opposite the first side. An FET is in a first area of the semiconductor carrier, and has a drain electrically coupled to a drain contact area at the first side and a source electrically coupled to a source contact area at the second side. First circuit elements are in a second area of the semiconductor carrier. The second area is electrically insulated from the semiconductor carrier surrounding the second area via a trench insulation extending through the semiconductor carrier from the first side to the second side. An interconnection level electrically interconnects the first circuit elements at the second side, and is electrically insulated from the source contact area in the entire second area via an insulating layer at the second side.

Abstract: A semiconductor device (100) including a cell region and a peripheral region around the cell region, the cell region including: a first semiconductor layer (1) having a first conductivity type; a second semiconductor layer (2) which is formed in an island shape on the surface of the first semiconductor layer and has a second conductivity type different from the first conductivity type; a third semiconductor layer (3) which is formed in an island shape on the surface of the second semiconductor layer and has the first conductivity type; and a plurality of gate trenches (11) penetrating the second and third semiconductor layer and reaching the inside of the first semiconductor layer, and the peripheral region including: a plurality of peripheral trenches (14) penetrating the second and third semiconductor layers and reaching the inside of the first semiconductor layer; and a termination layer (6) which is formed in an island shape in the surface of the first semiconductor layer and has the first conductivity ty

Abstract: A semiconductor device is provided that includes a fin having a first upper gate on a sidewall of the fin in a first trench and a second upper gate formed on the opposite sidewall of the fin. The device also includes a first lower gate on the sidewall and a second lower gate on the opposite sidewall, wherein the first upper gate is formed above the first lower gate and the second upper gate is formed above the second lower gate. Methods of manufacturing and operating the device are also included. A method of operation may include biasing the first upper gate and second upper gate to preselect the transistors of a fin and then biasing the first lower gate and second lower gate to operate the transistors of the fin.

Abstract: A semiconductor device is provided that includes a fin having a first gate and a second gate formed on a first sidewall of the fin in a first trench, wherein the first gate is formed above the second gate. The device includes a third gate and a fourth gate formed on a second sidewall of the fin in a second trench, wherein the third gate is formed above the fourth gate. Methods of manufacturing and operating the device are also included. A method of operation may include biasing the first gate and the fourth gate to create a current path across the fin.

Abstract: A vertical diffused metal oxide semiconductor (DMOS) field-effect transistors (FET), has a cell structure with a substrate; an epitaxial layer or well of the first conductivity type on the substrate; first and second base regions of the second conductivity type arranged within the epitaxial layer or well and spaced apart by a predefined distance; first and second source regions of a first conductivity type arranged within the first and second base region, respectively; a gate structure insulated from the epitaxial layer or well by an insulation layer and arranged above the region between the first and second base regions and covering at least partly the first and second base region, wherein the gate structure comprises first and second gates being spaced apart wherein each gate covers a respective portion of the base region.

Abstract: A vertical diffused metal oxide semiconductor (DMOS) field-effect transistors (FET) comprises a substrate of a first conductivity type forming a drain region; an epitaxial layer of the first conductivity type on said substrate; first and second base regions of the second conductivity type within said epitaxial layer, spaced apart by a predefined distance; first and second source regions of a first conductivity type arranged in said first and second base regions, respectively, wherein said first and second base region is operable to form first and second lateral channels between said source region and said epitaxial layer; a gate structure insulated from said epitaxial layer by an insulation layer and arranged above the region between the first and second base regions and wherein the gate structure comprises first and second gate regions, each gate region only covering the first and second channel, respectively within said first and second base region.

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: An integrated circuit structure includes a high-voltage well (HVW) region in a semiconductor substrate; a first double diffusion (DD) region in the HVW region; and a second DD region in the HVW region. The first DD region and the second DD region are spaced apart from each other by an intermediate portion of the HVW region. A recess extends from a top surface of the semiconductor substrate into the intermediate portion of the HVW region and the second DD region. A gate dielectric extends into the recess and covers a bottom of the recess. A gate electrode is over the gate dielectric. A first source/drain region is in the first DD region. A second source/drain region is in the second DD region.

Abstract: A plurality of vertical channels of semiconductor material are formed to extend in a vertical direction through the plurality of insulation layers and the plurality of conductive patterns, a gate insulating layer between the conductive pattern and the vertical channels that insulates the conductive pattern from the vertical channels. Conductive contact regions of the at least two of the conductive patterns are in a stepped configuration. An etch stop layer is positioned on the conductive contact regions, wherein the etch stop layer has a first portion on a first one of the plurality of conductive patterns and has a second portion on a second one of the plurality of conductive patterns, wherein the first portion is of a thickness that is greater than a thickness of the second portion.

Abstract: Disclosed herein is a semiconductor device, including: a first semiconductor region of a first conductivity type; a second semiconductor region having pairs of first pillar regions of the first conductivity type, and second pillar regions of a second conductivity type alternately provided; a third semiconductor region of the second conductivity type; a fourth semiconductor region of the first conductivity type; and control electrodes each provided within a trench through an insulating film, a sidewall of the trench being formed so as to contact each of the third semiconductor region and the fourth semiconductor region.

Abstract: Provided is a semiconductor device including a substrate having active patterns extending between first trenches and between second trenches (the first and second trenches intersecting each other), and gate patterns disposed within the first trenches, wherein each of the active patterns includes lower and upper impurity regions, and a channel region between the lower and upper impurity regions, the lower and upper impurity regions being vertically spaced apart from each other and having a conductivity type different from the substrate, and the channel region having the same conductivity type as the substrate, and a bottom surface of the gate pattern is closer to a bottom surface of the first trench than the lower impurity region.

Abstract: A semiconductor device may include a semiconductor layer having a convex portion and a concave portion surrounding the convex portion. The semiconductor device may further include a protrusion type isolation layer filling the concave portion and extending upward so that an uppermost surface of the isolation layer is a at level higher that an uppermost surface of the convex portion.

Abstract: A three dimensional (3D) semiconductor device includes; a vertical channel extending from a lower end proximate a substrate to an upper end and connecting a plurality of memory cells, and a cell array comprising the plurality of cells, wherein the cell array is arranged in a gate stack of layers having a stair-stepped structure disposed on the substrate. The gate stack includes a lower layer including a lower select line coupled to a lower non-memory transistor proximate the lower end, upper layers including conductive lines respectively coupled to an upper non-memory transistor proximate the upper end and connected as a single conductive piece to form an upper select line, and intermediate layers respectively including a word line and coupled to a cell transistor, wherein the intermediate layers are disposed between the lower select line and the upper select line.

Abstract: A semiconductor device has a plurality of vertical channels extending upright on a substrate, a plurality of bit lines extending among the vertical channels, a plurality of word lines which include a plurality of gates disposed adjacent first sides of the vertical channels, respectively, and a plurality of conductive elements disposed adjacent second sides of the vertical channels opposite the first sides. The conductive elements can provide a path to the substrate for charge carriers which have accumulated in the associated vertical channel to thereby mitigate a so-called floating effect.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed, which can form a gate electrode material only in a recess of a buried gate cell structure, improve a Gate Induced Drain Leakage (GIDL) of a gate electrode material and a junction (i.e., drain region), prevent the gate electrode material from overlapping with the junction (i.e., drain region), and adjust the depth of junction, thereby improving channel resistance. The method for manufacturing a semiconductor device includes forming a device isolation region defining an active region over a semiconductor substrate, burying a gate electrode material in the semiconductor substrate, forming a gate electrode pattern by etching the gate electrode material, wherein the gate electrode pattern is formed at sidewalls of the active region including a source region, and forming a capping layer in the exposed active region.

Abstract: A power semiconductor device having low gate input resistance and a manufacturing method thereof are provided. The power semiconductor device includes a substrate, at least a trench transistor, a conductive layer, a metal contact plug, an insulating layer, an interlayer dielectric, a gate metal layer, and a source metal layer. The metal contact plug can serve as a buried gate metal bus line, and the metal contact plug can pass under the source metal layer and keeps the area of the source metal layer complete. Accordingly, the present invention can provide a lower gate input resistance without dividing the source metal layer, so the source metal layer can have a larger and complete area for the following packaging and bonding process.

Abstract: Disclosed herein is a semiconductor device including: a first conductivity type semiconductor base body; a first conductivity type pillar region; second conductivity type pillar regions; element and termination regions provided in the first and second conductivity type pillar regions, transistors being formed in the element region, and no transistors being formed in the termination region; body regions; a gate insulating film; gate electrodes; source regions; and body potential extraction regions, wherein voids are formed in the second conductivity type pillar regions of the termination region.

Abstract: A semiconductor device includes the following elements. A semiconductor substrate includes an isolation region. The semiconductor substrate has a groove in the isolation region. A pad electrode is disposed in the groove. A pad contact plug is disposed in the groove. The pad contact plug is disposed on the pad electrode. A gate contact plug is disposed on the pad contact plug. The gate contact plug is electrically coupled through the pad contact plug to the pad electrode. An insulating side wall is disposed in the groove. The insulating side wall covers side surfaces of the pad contact plug and a lower portion of the gate contact plug, and the insulating side wall covers a part of an upper surface of the pad electrode.

Abstract: A method for forming an opening within a semiconductor material comprises forming a neck portion, a rounded portion below the neck portion and, in some embodiments, a protruding portion below the rounded portion. This opening may be filled with a conductor, a dielectric, or both. Embodiments to form a transistor gate, shallow trench isolation, and an isolation material separating a transistor source and drain are disclosed. Device structures formed by the method are also described.

Abstract: A semiconductor device of the present invention includes: a semiconductor substrate of a first conductive type; an epitaxial layer of the first conductive type formed on the semiconductor substrate and having a protrusion formed on a surface thereof; a well region of a second conductive type formed on the surface of the epitaxial layer at each side of the protrusion; a source region of the first conductive type selectively formed in a surface of the well region; a gate insulating film formed so as to cover at least the protrusion and the surface of the well region; and a gate electrode formed on a part of the gate insulating film corresponding to the protrusion. The gate insulating film is thicker in a region thereof corresponding to an upper surface of the protrusion than the other regions thereof.

Abstract: A technology is a semiconductor device and a method of manufacturing the same, capable of reducing capacitance with a storage node contact plug while maintaining a height and resistance of a bit line, by thickly forming a spacer between a bit line and the storage node contact plug. A semiconductor device includes a device isolation layer defining a plurality of active regions formed in a semiconductor substrate, a storage node contact hole exposing two neighboring active regions, a storage node contact plug material provided in the storage node contact hole, a bit line region that divides the storage node contact plug material into two parts and that has a convex portion at a lower portion of a sidewall, a spacer formed over a sidewall of the bit line region including the convex portion and a bit line formed in the bit line region.