Abstract: A super-junction semiconductor substrate is configured in such a manner that an n-type semiconductor layer of a parallel pn structure is opposed to a boundary region between an active area and a peripheral breakdown-resistant structure area. A high-concentration region is formed at the center between p-type semiconductor layers that are located on both sides of the above n-type semiconductor layer. A region where a source electrode is in contact with a channel layer is formed over the n-type semiconductor layer. A portion where the high-concentration region is in contact with the channel layer functions as a diode. The breakdown voltage of the diode is set lower than that of the device.

Abstract: A semiconductor device including a drain region of a first conductivity type formed on a semiconductor substrate; an element forming region that is provided on the drain region and that has a concave portion reaching the drain region; a gate electrode disposed in the concave portion; a superjunction structure portion that is disposed in the element forming region and that is formed by alternately arranging a drift layer of the first conductivity type penetrated by the concave portion and a resurf layer of a second conductivity type being in contact with the drift layer on the semiconductor substrate; and a base region of the second conductivity type that is disposed on the superjunction structure portion so as to be in contact with the drift layer in the element forming region, that is penetrated by the concave portion, and that faces the gate electrode with the gate insulating film therebetween.

Abstract: An integrated circuit includes a power MOS transistor which comprises a drain region, a trench gate, a source region, a well region, a deep well region and a substrate region. The drain region has a doping region of a first conductivity type connected to a drain electrode. The trench gate has an insulating layer and extends into the drain region. The source region has a doping region of the first conductivity type connected to a source electrode. The well region is doped with a second conductivity type, formed under the source region, and connected to the source electrode. The deep well region is doped with the first conductivity type and is formed under the drain region and the well region. The substrate region is doped with the second conductivity type and is formed under the deep well region. The drain region is formed at one side of the trench gate and the source region is formed at the opposing side of the trench gate such that the trench gate laterally connects the source region and the drain region.

Abstract: An electronic device can include a first layer having a primary surface, a well region lying adjacent to the primary surface, and a buried doped region spaced apart from the primary surface and the well region. The electronic device can also include a trench extending towards the buried doped region, wherein the trench has a sidewall, and a sidewall doped region along the sidewall of the trench, wherein the sidewall doped region extends to a depth deeper than the well region. The first layer and the buried region have a first conductivity type, and the well region has a second conductivity type opposite that of the first conductivity type. The electronic device can include a conductive structure within the trench, wherein the conductive structure is electrically connected to the buried doped region and is electrically insulated from the sidewall doped region. Processes for forming the electronic device are also described.

Abstract: Provided is a semiconductor device in which on-resistance is largely reduced. In a region (2a) of an N type epitaxial layer (2) of the semiconductor device 20, each region between neighboring trenches (3) is blocked with a depletion layer (14) formed around a trench (3) so that a current passage (12) is interrupted, while a part of the depletion layer (14) formed around the trench (3) is deleted so that the current passage (12) is opened. In a region (2b), a junction portion (8) between the N type epitaxial layer (2) and a P+ type diffusion region (7) makes a Zener diode (8).

Abstract: A DMOS transistor with a lower on-state drain-to-source resistance and a higher breakdown voltage utilizes a slanted super junction drift structure that lies along the side wall of an opening with the drain region at the bottom of the opening and the source region near the top of the opening.

Abstract: A method for manufacturing compatible vertical double diffused metal oxide semiconductor (VDMOS) transistor and lateral double diffused metal oxide semiconductor (LDMOS) transistor includes: providing a substrate having an LDMOS transistor region and a VDMOS transistor region; forming an N-buried region in the substrate; forming an epitaxial layer on the N-buried layer region; forming isolation regions in the LDMOS transistor region and the VDMOS transistor region; forming a drift region in the LDMOS transistor region; forming gates in the LDMOS transistor region and the VDMOS transistor region; forming PBODY regions in the LDMOS transistor region and the VDMOS transistor region; forming an N-type GRADE region in the LDMOS transistor region; forming an NSINK region in the VDMOS transistor region, where the NSINK region is in contact with the N-buried layer region; forming sources and drains in the LDMOS transistor region and the VDMOS transistor region; and forming a P+ region in the LDMOS transistor region,

Abstract: A semiconductor device (A1) includes a semiconductor layer having a first face with a trench (3) formed thereon and a second face opposite to the first face, a gate electrode (41), and a gate insulating layer (5). The semiconductor layer includes a first n-type semiconductor layer (11), a second n-type semiconductor layer (12), a p-type semiconductor layer (13), and an n-type semiconductor region (14). The trench (3) is formed so as to penetrate through the p-type semiconductor layer (13) and to reach the second n-type semiconductor layer (12). The p-type semiconductor layer (13) includes an extended portion extending to a position closer to the second face of the semiconductor layer than the trench (3) is. Such structure allows suppressing dielectric breakdown in the gate insulating layer (5).

Abstract: The invention discloses a manufacture method and structure of a power transistor, which comprises a lower electrode, a substrate, a drift region, two first conductive regions, two second conductive regions, two gate units, an isolation structure and an upper electrode; wherein the two second conductive region are between the two first conductive regions and the drift region; the two gate units are on the two second conductive regions; the isolation structure covers the surface of the two gate units; the upper electrode covers; the surface of the isolation structure and connects to the two first conductive regions and the two second conductive regions electrically. When the substrate is of the first conductive type, the structure can be used as MOSFET. When the substrate is of the second conductive type, the structure can be used as IGBT. This structure has a small gate electrode area, which leads to less Qg, Qgd and Rdson and improves device performance.

Abstract: MOSFET devices for RF applications that use a trench-gate in place of the lateral gate conventionally used in lateral MOSFET devices. A trench-gate provides devices with a single, short channel for high frequency gain. Embodiments of the present invention provide devices with an asymmetric oxide in the trench gate, as well as LDD regions that lower the gate-drain capacitance for improved RF performance. Refinements to these TG-LDMOS devices include placing a source-shield conductor below the gate and placing two gates in a trench-gate region. These improve device high-frequency performance by decreasing gate-to-drain capacitance. Further refinements include adding a charge balance region to the LDD region and adding source-to-substrate or drain-to-substrate vias.

Abstract: A field effect transistor includes a plurality of trenches extending into a semiconductor region of a first conductivity type. The plurality of trenches includes a plurality of gated trenches and a plurality of non-gated trenches. A body region of a second conductivity extends in the semiconductor region between adjacent trenches. A dielectric material fills a bottom portion of each of the gated and non-gated trenches. A gate electrode is disposed in each gated trench. A conductive material of the second conductivity type is disposed in each non-gated trench such that the conductive material and contacts corresponding body regions along sidewalls of the non-gated trench.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor layer of a first conductive type, and a periodic array structure having a second semiconductor layer of a first conductive type and a third semiconductor layer of a second conductive type periodically arrayed on the first semiconductor layer in a direction parallel with a major surface of the first semiconductor layer. The second semiconductor layer and the third semiconductor layer are disposed in dots on the first semiconductor layer. A periodic structure in the outermost peripheral portion of the periodic array structure is different from a periodic structure of the periodic array structure in a portion other than the outermost peripheral portion.

Abstract: A semiconductor device includes a semiconductor substrate having at least a pn-junction arranged in the semiconductor substrate. At least a field electrode is arranged at least next to a portion of the pn-junction, wherein the field electrode is insulated from the semiconductor substrate. A switching device is electrically connected to the field electrode and adapted to apply selectively and dynamically one of a first electrical potential and a second electrical potential, which is different to the first electrical potential, to the field electrode to alter the avalanche breakdown characteristics of the pn-junction.

Abstract: A semiconductor structure is provided. A second area is disposed between first and third areas. An epitaxial layer is on a substrate. A body layer is in the epitaxial layer in first and second areas. First and second gates are in the body layer and in a portion of the epitaxial layer. The first gate is in the substrate and partially in first and second areas. The second gate is in the substrate and partially in second and third areas. A first contact plug is in a portion of the body layer in the first area. A second contact plug is at least in the epitaxial layer in the third area and contacts the epitaxial layer and the second gate. The first contact plug is electrically connected to the second contact plug. A first doped region is in the body layer between the first contact plug and the first gate.

Abstract: A transistor structure optimizes current along the A-face of a silicon carbide body to form an AMOSFET that minimizes the JFET effect in the drift region during forward conduction in the on-state. The AMOSFET further shows high voltage blocking ability due to the addition of a highly doped well region that protects the gate corner region in a trench-gated device. The AMOSFET uses the A-face conduction along a trench sidewall in addition to a buried channel layer extending across portions of the semiconductor mesas defining the trench. A doped well extends from at least one of the mesas to a depth within the current spreading layer that is greater than the depth of the trench. A current spreading layer extends between the semiconductor mesas beneath the bottom of the trench to reduce junction resistance in the on-state. A buffer layer between the trench and the deep well further provides protection from field crowding at the trench corner.

Abstract: This invention discloses a semiconductor power device disposed in a semiconductor substrate and the semiconductor substrate has a plurality of trenches. Each of the trenches is filled with a plurality of epitaxial layers of alternating conductivity types constituting nano tubes functioning as conducting channels stacked as layers extending along a sidewall direction with a “Gap Filler” layer filling a merging-gap between the nano tubes disposed substantially at a center of each of the trenches. The “Gap Filler” layer can be very lightly doped Silicon or grown and deposited dielectric layer. In an exemplary embodiment, the plurality of trenches are separated by pillar columns each having a width approximately half to one-third of a width of the trenches.

Abstract: Semiconductor device fabrication method and devices are disclosed. A device may be fabricated by forming in a semiconductor layer; filling the trench with an insulating material; removing selected portions of the insulating material leaving a portion of the insulating material in a bottom portion of the trench; forming one or more spacers on one or more sidewalls of a remaining portion of the trench; anisotropically etching the insulating material in the bottom portion of the trench using the spacers as a mask to form a trench in the insulator; removing the spacers; and filling the trench in the insulator with a conductive material. Alternatively, an oxide-nitride-oxide (ONO) structure may be formed on a sidewall and at a bottom of the trench and one or more conductive structures may be formed in a portion of the trench not occupied by the ONO structure.

Abstract: In a semiconductor device according to the present invention, a p-type well region disposed in an outer peripheral portion of the power semiconductor device is divided into two parts, that is, an inside and an outside, and a field oxide film having a greater film thickness than the gate insulating film is provided on a well region at the outside to an inside of an inner periphery of the well region. Therefore, it is possible to prevent, in the gate insulating film, a dielectric breakdown due to the voltage generated by the flow of the displacement current in switching.

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

Abstract: A semiconductor device includes a substrate, an active gate trench in the substrate, the active gate trench has a first top gate electrode and a first bottom source electrode, and a gate runner trench comprising a second top gate electrode and a second bottom source electrode. The second top gate electrode is narrower than the second bottom source electrode.

Abstract: A semiconductor device includes: a semiconductor substrate; an interlayer film on the substrate; a surface electrode on the interlayer film; a surface pad on the surface electrode; a backside electrode on the substrate; an element area including a cell portion having a vertical semiconductor element and a removal portion having multiple contact regions; and an outer periphery area. The surface electrode in the removal portion is electrically coupled with each contact region through a first contact hole in the interlayer film. The surface electrode in the cell portion is electrically coupled with the substrate through a second contact hole in the interlayer film. A part of the surface electrode in the removal portion facing each contact region is defined as a contact portion. The surface electrode includes multiple notches on a shortest distance line segment between each contact portion and the surface pad.

Abstract: A module includes a semiconductor chip having at least a first terminal contact surface and a second terminal contact surface. A first bond element made of a material on the basis of Cu is attached to the first terminal contact surface, and a second bond element is attached to the second terminal contact surface. The second bond element is made of a material different from the material of the first bond element or is made of a type of bond element different from the type of the first bond element.

Abstract: Provided is a semiconductor device capable of suppressing deterioration in characteristics even when an Avalanche phenomenon occurs in the semiconductor device. The semiconductor device includes a first conductive type drift region; a second conductive type body region disposed on a front surface side of the drift region; a gate trench penetrating the body region and extending to the drift region; a gate electrode disposed within the gate trench; an insulator disposed between the gate electrode and a wall surface of the gate trench; and a second conductive type diffusion region surrounding a bottom portion of the gate trench. An impurity concentration and dimension of the diffusion region are adjusted such that a breakdown is to occur at a p-n junction between the diffusion region and the drift region when an Avalanche phenomenon is occurring.

Abstract: This invention discloses an inverted field-effect-transistor (iT-FET) semiconductor device that includes a source disposed on a bottom and a drain disposed on a top of a semiconductor substrate. The semiconductor power device further comprises a trench-sidewall gate placed on sidewalls at a lower portion of a vertical trench surrounded by a body region encompassing a source region with a low resistivity body-source structure connected to a bottom source electrode and a drain link region disposed on top of said body regions thus constituting a drift region. The drift region is operated with a floating potential said iT-FET device achieving a self-termination.

Abstract: A novel semiconductor power transistor is presented. The semiconductor structure is simple and is based on a MOS configuration with a drift region and an additional gate that modulates the carrier density in the drift region, so that the control on the carrier transport is enhanced and the specific on-resistance per area is reduced. This characteristic enables the use of short gate lengths while maintaining the electric field under the gate within reasonable values in high voltage applications, without increasing the device on-resistance. It offers the advantage of extremely lower on-resistance for the same silicon area while improving on its dynamic performances with respect to the standard CMOS technology. Another inherent advantage is that the switching gate losses are smaller due to lower VGS voltages required to operate the device.

Abstract: A method of forming a semiconductor device comprises providing a semiconductor substrate, providing a semiconductor layer of a first conductivity type over the semiconductor substrate, forming a first region of the first conductivity type in the semiconductor layer, and forming a control region over the semiconductor layer and over part of the first region. A mask layer is formed over the semiconductor layer and outlines a first portion of a surface of the semiconductor layer over part of the first region. Semiconductor material of a second conductivity type is provided to the outlined first portion to provide a second region in the semiconductor layer.

Abstract: The present invention relates to a semiconductor device. The device comprises a semiconductor substrate. A semiconductor drift region is on the semiconductor substrate. The semiconductor drift region comprises a semiconductor region of a first conduction type and a semiconductor region of a second conduction type. The semiconductor region of the first conduction type and the semiconductor region of the second conduction type form a superjunction structure. A high-K dielectric is on the semiconductor substrate. The high-K dielectric is adjacent to the semiconductor region of the second conduction type. An active region is on the semiconductor drift region. A trench gate structure is on the high-K dielectric, the trench gate structure being adjacent to the active region. The semiconductor region of the second conduction type is formed by shallow angle ion implantation, thus its width is narrow and its concentration is high.

Abstract: A semiconductor device includes an n-type drain layer, an n-type base layer provided on the n-type drain layer, a p-type base layer and an n-type source layer partially formed in surface layer portions of the n-type base layer and the p-type base layer, respectively, a gate insulation film formed on a surface of the p-type base layer between the n-type source layer and the n-type base layer, a gate electrode formed on the gate insulation film facing the p-type base layer across the gate insulation film, a p-type column layer formed within the n-type base layer to extend from the p-type base layer toward the n-type drain layer, a depletion layer alleviation region arranged between the p-type column layer and the n-type drain layer and including first baryons converted to donors, a source electrode connected to the n-type source layer, and a drain electrode connected to the n-type drain layer.

Abstract: A semiconductor package device houses a die which comprises a power device, and the die further includes a silicon region over a substrate, a first plurality of trenches extending in the silicon region; a contiguous sinker trench extending along the perimeter of the die so as to completely surround the first plurality of trenches, the sinker trench extending from a top surface of the die through the silicon region, the sinker trench being lined with an insulator only along the sinker trench sidewalls so that a conductive material filling the sinker trench makes electrical contact with the substrate along the bottom of the sinker trench and makes electrical contact with an interconnect layer along the top of the sinker trench; and a plurality of interconnect balls arranged in a grid array, an outer group of the plurality of interconnect balls electrically connecting to the conductive material in the sinker trench.

Abstract: An edge termination structure includes a final dielectric trench containing permanent charge. The final dielectric trench is surrounded by first conductivity type semiconductor material (doped by lateral outdiffusion from the trenches), which in turn is laterally surrounded by second conductivity type semiconductor material.

Abstract: A semiconductor device according to the present invention includes a semiconductor layer. A first conductivity type region is formed on a base layer portion of the semiconductor layer. A body region of a second conductivity type is formed on the semiconductor layer to be in contact with the first conductivity type region. A trench in which a gate electrode is embedded through a gate insulating film is formed on the semiconductor layer. The trench penetrates through the body region, so that a deepest portion thereof reaches the first conductivity type region. A source region of the first conductivity type is formed on a surface layer portion of the semiconductor layer around the trench. The gate insulating film includes a thick-film portion having a relatively large thickness on a bottom surface of the trench.

Abstract: A semiconductor device includes a source, a drain, and a gate configured to selectively enable a current to pass between the source and the drain. The semiconductor device includes a drift zone between the source and the drain and a first field plate adjacent the drift zone. The semiconductor device includes a dielectric layer electrically isolating the first field plate from the drift zone and charges within the dielectric layer close to an interface of the dielectric layer adjacent the drift zone.

Abstract: A screen oxide film is formed on an n? drift layer (2) that is disposed on an anterior side of an n-type low-resistance layer (1), and a nitride film is formed on the screen oxide film. The nitride film is photo-etched using a first mask and thereby, a nitride shielding film (61) is formed. N-type impurity ions at a concentration higher than that of the n? drift layer are implanted through the nitride shielding film (61) from an anterior side of a semiconductor substrate and are thermally diffused and thereby, an n counter layer (7) is formed. The screen oxide film is removed. A gate oxide film (3a) is formed. A gate electrode (9) is formed on the gate oxide film (3a). P-type impurity ions are implanted from the anterior side of the semiconductor substrate using the gate electrode (9) and the nitride shielding film (61) as a mask and thereby, p? well regions (10) are formed.

Abstract: A manufacturing method of a depletion mode trench semiconductor device includes following steps. Firstly, a substrate including a drift epitaxial layer disposed thereon is provided. A trench is disposed in the drift epitaxial layer. A gate dielectric layer is formed on an inner sidewall of the trench and an upper surface of the drift epitaxial layer. A base doped region is formed in the drift epitaxial layer and adjacent to a side of the trench. A thin doped region is formed and conformally contacts the gate dielectric layer. A gate material layer is formed to fill the trench. A source doped region is formed in the base doped region, and the source doped region overlaps the thin doped region at a side of the trench. Finally, a contact doped region is formed to overlap the thin doped region, and the contact doped region is adjacent to the source doped region.

Abstract: A semiconductor device embodiment includes a substrate, an active gate trench in the substrate, and an asymmetric trench in the substrate. The asymmetric trench has a first trench wall and a second trench wall, the first trench wall is lined with oxide having a first thickness, and the second trench wall is lined with oxide having a second thickness that is different from the first thickness. Another semiconductor device embodiment includes a substrate, an active gate trench in the substrate; and a source polysilicon pickup trench in the substrate. The source polysilicon pickup trench includes a polysilicon electrode, and top surface of the polysilicon electrode is below a bottom of a body region. Another semiconductor device includes a substrate, an active gate trench in the substrate, the active gate trench has a first top gate electrode and a first bottom source electrode, and a gate runner trench comprising a second top gate electrode and a second bottom source electrode.

Abstract: Exemplary power semiconductor devices with features providing increased breakdown voltage and other benefits are disclosed.

Abstract: A structure and method of fabricating the structure. The structure including: a dielectric isolation in a semiconductor substrate, the dielectric isolation extending in a direction perpendicular to a top surface of the substrate into the substrate a first distance, the dielectric isolation surrounding a first region and a second region of the substrate, a top surface of the dielectric isolation coplanar with the top surface of the substrate; a dielectric region in the second region of the substrate; the dielectric region extending in the perpendicular direction into the substrate a second distance, the first distance greater than the second distance; and a first device in the first region and a second device in the second region, the first device different from the second device, the dielectric region isolating a first element of the second device from a second element of the second device.

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

Abstract: A semiconductor device has a semiconductor substrate having an upper main surface and a lower main surface. The semiconductor substrate includes a drain layer, a main base region, an underpad base region and a source region. The semiconductor device includes a first main electrode connected to the main base region and the source region and not connected to the underpad base region, a gate electrode opposed to a channel region in the main base region interposed between the drain layer and the source region with a gate insulating film provided therebetween, a conductive gate pad opposed to an exposed surface of the underpad base region in the upper main surface with an insulating layer interposed therebetween and the conductive gate pad is connected to the gate electrode, and a second main electrode connected to the lower main surface.

Abstract: A field effect transistor (FET) includes a plurality of trenches extending into a silicon layer, each trench having upper sidewalls that fan out. Contact openings extend into the silicon layer between adjacent trenches such that each trench and an adjacent contact opening form a common upper sidewall portion. Body regions extend between adjacent trenches. Source regions that are self-aligned to corresponding trenches extend in the body regions adjacent opposing sidewalls of each trench, and have a conductivity type opposite that of the body regions.

Abstract: A semiconductor device and a method of forming thereof has a base body has a field stopping layer, a drift layer, a current spreading layer, a body region, and a source contact region layered in the order on a substrate. A trench that reaches the field stopping layer or the substrate is provided. A gate electrode is provided in the upper half section in the trench. In a section deeper than the position of the gate electrode in the trench, an insulator is buried that has a normal value of insulation breakdown electric field strength equal to or greater than the value of the insulation breakdown electric field strength of the semiconductor material of the base body. This inhibits short circuit between a gate and a drain due to insulation breakdown of an insulator film at the bottom of the trench to realize a high breakdown voltage in a semiconductor device using a semiconductor material such as SiC. The sidewall surfaces of the trench located below the gate electrode is inclined to form a trapezoidal profile.

Abstract: The invention is related to a semiconductor device with alternately arranged P-type and N-type thin semiconductor layers and method for manufacturing the same. For P-type device, the method includes trench formation, thermal oxide formation on trench sidewalls, N-type silicon formation in trenches, N-type impurity diffusion through thermal oxide into P-type epitaxial layer, oxidation of N-type silicon in trenches and oxide removal. In the semiconductor device, N-type thin semiconductor layers are formed by N-type impurity diffusion through oxide to P-type epitaxial layers, and trenches are filled with oxide. With this method, relatively low concentration impurity in high voltage device can be realized by current mass production process, and the device development cost and manufacturing cost are decreased.

Abstract: A method (and resultant structure) includes forming a semiconductor layer having plural stripe-like trenches, forming a gate electrode buried partially in each of the plural trenches, and introducing an impurity into the semiconductor layer by ion implantation after forming the gate electrode. The gate electrode has a buried portion formed in each of the trenches and a protruding portion situating above the buried portion and having a width larger than that of the buried portion. The introducing the impurity includes introducing an impurity into the semiconductor layer below the protruding portion by oblique ion implantation.

Abstract: A recessed channel transistor includes an isolation layer provided in a semiconductor substrate to define an active region. A trench is provided in the semiconductor substrate to extend across the active region. A gate insulation layer covers a sidewall and a bottom face of the trench and an upper face of the semiconductor substrate adjacent to an upper edge of the trench, wherein a portion of the gate insulation layer on the upper surface of the semiconductor substrate adjacent to the upper edge of the trench and on the sidewall of the trench extending to a first distance downwardly from the upper edge of the trench has a thickness greater than that of a portion of the gate insulation layer on the remaining sidewall and the bottom face of the trench. A gate electrode fills up the trench having the gate insulation layer formed therein.

Abstract: In one aspect, a lateral MOS device is provided. The lateral MOS device includes a gate electrode disposed at least partially in a gate trench to apply a voltage to a channel region, and a drain electrode spaced from the gate electrode, and in electrical communication with a drift region having a boundary with a lower end of the channel region. The device includes a gate dielectric layer in contact with the gate electrode, and disposed between the gate electrode and the drain electrode. The channel region is adjacent to a substantially vertical wall of the gate trench. The device includes a field plate contacting the gate electrode and configured to increase a breakdown voltage of the device.

Abstract: A high-voltage metal-oxide-semiconductor (HVMOS) device may include a source, a drain, a gate positioned proximate to the source, a drift region disposed substantially between the drain and a region of the gate and the source, and a self shielding region disposed proximate to the drain. A corresponding method is also provided.

Abstract: A method for forming a trench-gate FET includes the following steps. A plurality of trenches is formed extending into a semiconductor region. A gate dielectric is formed extending along opposing sidewalls of each trench and over mesa surfaces of the semiconductor region between adjacent trenches. A gate electrode is formed in each trench isolated from the semiconductor region by the gate dielectric. Well regions of a second conductivity type are formed in the semiconductor region. Source regions of the first conductivity type are formed in upper portions of the well regions. After forming the source regions, a salicide layer is formed over the gate electrode in each trench abutting portions of the gate dielectric. The gate dielectric prevents formation of the salicide layer over the mesa surfaces of the semiconductor region between adjacent trenches.

Abstract: A method of manufacturing a semiconductor device having a charge control trench and an active control trench with a thick oxide bottom includes forming a drift region, a well region extending above the drift region, an active trench extending through the well region and into the drift region, a charge control trench extending deeper into the drift region than the active trench, an oxide film that fills the active trench, the charge control trench and covers a top surface of the substrate, an electrode in the active trench, and source regions. The method also includes etching the oxide film off the top surface of the substrate and inside the active trench to leave a substantially flat layer of thick oxide having a target thickness at the bottom of the active trench.

Abstract: A SiC semiconductor device having a MOS structure includes: a SiC substrate; a channel region providing a current path; first and second impurity regions on upstream and downstream sides of the current path, respectively; and a gate on the channel region through the gate insulating film. The channel region for flowing current between the first and second impurity regions is controlled by a voltage applied to the gate. An interface between the channel region and the gate insulating film has a hydrogen concentration equal to or greater than 4.7×1020 cm?3. The interface provides a channel surface having a (000-1)-orientation surface.