Abstract: The upper end of a gate electrode is situated below the surface of a semiconductor substrate. An insulating layer is formed over the gate electrode and over the semiconductor substrate situated at the periphery thereof. The insulating layer has a first insulating film and a low oxygen permeable insulating film. The first insulating film is, for example, an NSG film and the low oxygen permeable insulating film is, for example, an SiN film. Further, a second insulating film is formed over the low oxygen permeable insulating film. The second insulating film is, for example, a BPSG film. The TDDB resistance of a vertical MOS transistor is improved by processing with an oxidative atmosphere after forming the insulating layer. Further since the insulating layer has the low oxygen permeable insulating film, fluctuation of the threshold voltage of the vertical MOS transistor can be suppressed.

Abstract: A method for fabricating a transistor including a bulb-type recess channel includes forming a bulb-type recess pattern in a substrate, forming a gate insulating layer over the substrate and the bulb-type recess pattern, forming a first gate conductive layer over the gate insulating layer, forming a void movement blocking layer over the first gate conductive layer in the bulb-type recess pattern, and forming a second gate conductive layer over the void movement blocking layer and the first gate conductive layer.

Abstract: A method for forming a semiconductor device is provided. The method includes providing a semiconductor body with a horizontal surface. An epitaxy hard mask is formed on the horizontal surface. An epitaxial region is formed by selective epitaxy on the horizontal surface relative to the epitaxy hard mask so that the epitaxial region is adjusted to the epitaxy hard mask. A vertical trench is formed in the semiconductor body. An insulated field plate is formed in a lower portion of the vertical trench and an insulated gate electrode is formed above the insulated field plate. Further, a method for forming a field-effect semiconductor device is provided.

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

Abstract: A method for manufacturing a semiconductor device is disclosed, which reduces a step difference between a peripheral region and a cell region. In the semiconductor device, a metal contact of the peripheral region is configured in a multi-layered structure. Prior to forming a bit line and a storage node contact in the cell region, a contact and a line are formed in the peripheral region, such that a step difference between the cell region and the peripheral region is reduced, resulting in a reduction in parasitic capacitance between lines.

Abstract: A transistor with a gate electrode structure is produced by providing a semiconductor body with a first surface, and with a first sacrificial layer extending in a vertical direction of the semiconductor body from the first surface. A first trench extending from the first surface into the semiconductor body is formed by removing the sacrificial layer in a section adjacent the first surface. A second trench is formed by isotropically etching the semiconductor body in the first trench. A third trench is formed below the second trench by removing at least a part of the first sacrificial layer below the second trench. A dielectric layer is formed which at least covers sidewalls of the third trench and which only covers sidewalls of the second trench. A gate electrode is formed on the dielectric layer in the second trench. The gate electrode and dielectric layer in the second trench form the gate electrode structure.

Abstract: A method for producing VDMOS transistors in which a specific layer arrangement and a specific method sequence allow setting up an improved gate contact when simultaneously producing source and gate contacts using a single contact hole mask (photo mask).

Abstract: A method of forming a semiconductor structure is provided. A second area is between first and third areas. An epitaxial layer is formed on a substrate. A first gate is formed in the epitaxial layer and partially in first and second areas. A second gate is formed in the epitaxial layer and partially in second and third areas. A body layer is formed in the epitaxial layer in first and second areas. A doped region is formed in the body layer in the first area. All of the doped region, the epitaxial layer and the second gate are partially removed to form a first opening in the doped region and in the body layer in the first area, and form a second opening in the epitaxial layer in the third area and in a portion of the second gate. A first metal layer is filled in first and second openings.

Abstract: A method for forming thick oxide at the bottom of a trench formed in a semiconductor substrate includes forming a conformal oxide film by a sub-atmospheric chemical vapor deposition process that fills the trench and covers a top surface of the substrate. The method also includes etching the oxide film off the top surface of the substrate and inside the trench to leave a substantially flat layer of oxide having a target thickness at the bottom of the trench.

Abstract: A field effect transistor device having a strained semiconductor channel region overlying a heterostructure-semiconductor on a metal substrate includes a first semiconductor layer overlying a first metal layer. The first semiconductor layer has a first semiconductor material and a second semiconductor material in a relaxed heterostructure and is heavily doped. A second semiconductor layer overlies the first semiconductor layer and has a first semiconductor material and a second semiconductor material in a relaxed heterostructure. The second semiconductor layer is more lightly doped than the first semiconductor layer. A trench extends into the second semiconductor layer and a channel region has a strained layer of the first semiconductor material adjacent a trench sidewall. The strained channel region provides enhanced carrier mobility and improves performance of the field effect transistor.

Abstract: A semiconductor device includes a substrate with a recess pattern, a gate electrode filling the recess pattern, a threshold voltage adjusting layer formed in the substrate under the recess pattern, a source/drain region formed in the substrate on both sides of the gate electrode and a gate insulation layer, with the recess pattern being disposed between the gate electrode and the substrate, wherein the thickness of the gate insulation layer formed in a region adjacent to the source/drain region is greater than the thickness of the gate insulation layer formed in a region adjacent to the threshold voltage adjusting layer.

Abstract: A method for fabricating trench DMOS transistor includes: forming an oxide layer and a barrier layer with photolithography layout sequentially on a semiconductor substrate; etching the oxide layer and the semiconductor substrate with the barrier layer as a mask to form a trench; forming a gate oxide layer on the inner wall of the trench; forming a polysilicon layer on the barrier layer, filling up the trench; etching back the polysilicon layer with the barrier layer mask to remove the polysilicon layer on the barrier layer to form a trench gate; removing the barrier layer and the oxide layer; implanting ions into the semiconductor substrate on both sides of the trench gate to form a diffusion layer; coating a photoresist layer on the diffusion layer and defining a source/drain layout thereon; implanting ions into the diffusion layer based on the source/drain layout with the photoresist layer mask to form the source/drain; forming sidewalls on both the sides of the trench gate after removing the photoresist la

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 non-volatile memory device may include a semiconductor substrate including an active region at a surface thereof, a first memory cell string on the active region, and a second memory cell string on the active region. The first memory cell string may include a first plurality of word lines crossing the active region between a first ground select line and a first string select line, and about a same first spacing may be provided between adjacent ones of the first plurality of word lines. The second memory cell string may include a second plurality of word lines crossing the active region between a second ground select line and a second string select line, and about the same first spacing may be provided between adjacent ones of the second plurality of word lines. Related methods are also discussed.

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 and a method for making a semiconductor device are disclosed. A trench mask may be applied to a semiconductor substrate, which is etched to form trenches with three different widths. A first conductive material is formed at the bottom of the trenches. A second conductive material is formed over the first conductive material. An insulator layer separates the first and second conductive materials. A first insulator layer is deposited on top of the trenches. A body layer is formed in a top portion of the substrate. A source is formed in the body layer. A second insulator layer is applied on top of the trenches and the source. A contact mask is applied on top of the second insulator layer. Source and gate contacts are formed through the second insulator layer. Source and gate metal are formed on top of the second insulator layer.

Abstract: A trench-typed power MOS transistor comprises a trench-typed gate area, which includes a gate conductor and an isolation layer. A thin sidewall region of the isolation layer is formed between the gate conductor and a well region. A thick sidewall region of the isolation layer is formed between the gate conductor and a double diffusion region. A thick bottom region of the isolation layer is formed between the gate conductor and a deep well region.

Abstract: Various structures and methods for improving the performance of trench-shielded power semiconductor devices and the like are described. An exemplary device comprises a semiconductor region having a surface, a first area of the semiconductor region, a well region of a first conductivity type disposed in the semiconductor region and around the first area, and a plurality of trenches extending in a semiconductor region. Each trench haves a first end disposed in a first portion of the well region, a second end disposed in a second portion of the well region, and a middle portion between the first and second ends and disposed in the first area. Each trench further having opposing sidewalls lined with a dielectric layer, and a conductive electrode disposed on at least a portion of the dielectric layer.

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: Disclosed are semiconductor devices and methods of making semiconductor devices. An exemplary embodiment comprises a semiconductor layer of a first conductivity type having a first surface, a second surface, and a graded net doping concentration of the first conductivity type within a portion of the semiconductor layer. The graded portion is located adjacent to the top surface of the semiconductor layer, and the graded net doping concentration therein decreasing in value with distance from the top surface of the semiconductor layer. The exemplary device also comprises an electrode disposed at the first surface of the semiconductor layer and adjacent to the graded portion.

Abstract: A fabrication method of a trenched power semiconductor structure with low gate charge is provided. Firstly, a substrate is provided. Then, a gate trench is formed in the substrate. Afterward, a dielectric layer is formed on the inner surfaces of the gate trench. Then, a spacer is formed on the dielectric layer covering the sidewall of the gate trench. Thereafter, a plug structure is formed in the space at the bottom of the gate trench, which is defined by the spacer. Then, a portion of the spacer is removed with the dielectric structure and the plug structure as an etching mask. Thereafter, a portion of the dielectric layer is removed with the remained spacer as an etching mask to expose the inner surface of the upper portion of the gate trench. Afterward, with the remained spacer being kept, a gate dielectric layer is formed on the inner surface of the upper portion of the gate trench, and then a polysilicon gate is filled into the upper portion of the gate trench.

Abstract: In a method of fabricating a semiconductor device having a MISFET of trench gate structure, a trench is formed from a major surface of a semiconductor layer of first conductivity type which serves as a drain region, in a depth direction of the semiconductor layer, a gate insulating film including a thermal oxide film and a deposited film is formed over the internal surface of the trench, and after a gate electrode has been formed in the trench, impurities are introduced into the semiconductor substrate of first conductivity type to form a semiconductor region of second conductivity type which serves as a channel forming region, and impurities are introduced into the semiconductor region of second conductivity type to form the semiconductor region of first conductivity type which serves as a source region.

Abstract: A vertically arranged laterally diffused metal-oxide-semiconductor (LDMOS) device comprises a trench extending into a semiconductor body toward a semiconductor substrate. The trench includes sidewalls, a bottom portion connecting the sidewalls, a dielectric material lining the trench and a diffusion agent layer lining the dielectric material. A lightly doped drain region adjoins the trench and extends laterally around the sidewalls from the diffusion agent layer into the semiconductor body. In one embodiment, a method for fabricating a vertically arranged LDMOS device comprises forming a trench extending into a semiconductor body toward a semiconductor substrate, the trench including sidewalls, a bottom portion connecting the sidewalls, a dielectric material lining the trench and a diffusion agent layer lining the dielectric material.

Abstract: This invention discloses a method of manufacturing a trenched semiconductor power device with split gate filling a trench opened in a semiconductor substrate wherein the split gate is separated by an inter-poly insulation layer disposed between a top and a bottom gate segments. The method further includes a step of forming the inter-poly layer by applying a RTP process after a HDP oxide deposition process to bring an etch rate of the HDP oxide layer close to an etch rate of a thermal oxide.

Abstract: A method for fabricating a transistor including a bulb-type recess channel includes forming a bulb-type recess pattern in a substrate, forming a gate insulating layer over the substrate and the bulb-type recess pattern, forming a first gate conductive layer over the gate insulating layer, forming a void movement blocking layer over the first gate conductive layer in the bulb-type recess pattern, and forming a second gate conductive layer over the void movement blocking layer and the first gate conductive layer.

Abstract: A power semiconductor device includes a backside metal layer, a substrate formed on the backside metal layer, a semiconductor layer formed on the substrate, and a frontside metal layer. The semiconductor layer includes a first trench structure including a gate oxide layer formed around a first trench with poly-Si implant, a second trench structure including a gate oxide layer formed around a second trench with poly-Si implant, a p-base region formed between the first trench structure and the second trench structure, a plurality of n+ source region formed on the p-base region and between the first trench structure and the second trench structure, a dielectric layer formed on the first trench structure, the second trench structure, and the plurality of n+ source region. The frontside metal layer is formed on the semiconductor layer and filling gaps formed between the plurality of n+ source region on the p-base region.

Abstract: Methods of forming a gate electrode can be provided by forming a trench in a substrate, conformally forming a polysilicon layer to provide a polysilicon conformal layer in the trench defining a recess surrounded by the polysilicon conformal layer, wherein the polysilicon conformal layer is formed to extend upwardly from a surface of the substrate to have a protrusion and the protrusion has a vertical outer sidewall adjacent the surface of the substrate, forming a tungsten layer in the recess to form an upper surface that includes an interface between the polysilicon conformal layer and the tungsten layer, and forming a capping layer being in direct contact with top surfaces of the polysilicon conformal layer and the tungsten layer without any intervening layers.

Abstract: A recess gate of a semiconductor device is provided, comprising: a substrate having a recess formed therein; a metal layer formed at the bottom of the recess; a polysilicon layer formed over the metal layer; and a source region and a drain region formed adjacent to the polysilicon layer and spaced from the metal layer.

Abstract: A trench-typed power MOS transistor comprises a trench-typed gate area, which includes a gate conductor and an isolation layer. A thin sidewall region of the isolation layer is formed between the gate conductor and a well region. A thick sidewall region of the isolation layer is formed between the gate conductor and a double diffusion region. A thick bottom region of the isolation layer is formed between the gate conductor and a deep well region.

Abstract: A semiconductor substrate has a trench in a first main surface. An insulated gate field effect part includes a gate electrode formed in the first main surface. A potential fixing electrode fills the trench and has an expanding part expanding on the first main surface so that a width thereof is larger than the width of the trench. An emitter electrode is formed on the first main surface and insulated from the gate electrode electrically and connected to a whole upper surface of the expanding part of the potential fixing electrode. Thus, a semiconductor device capable of enhancing reliability in order to prevent an aluminum spike from generating and a manufacturing method thereof can be provided.

Abstract: A trench semiconductor device and a method of making the same are provided. The trench semiconductor device includes a trench MOS device and a trench ESD protection device. The trench ESD protection device is electrically connected between the gate electrode and source electrode of the trench MOS device so as to provide ESD protection. The fabrication of the ESD protection device is integrated into the process of the trench MOS device, and therefore no extra mask is required to define the doped regions of the trench ESD protection device. Consequently, the trench semiconductor device is advantageous for its simplified manufacturing process and low cost.

Abstract: A semiconductor device includes a device isolation structure having a grounded conductive layer to define an active region, and a gate formed over the active region and the device isolation structure.

Abstract: A semiconductor device includes a gate electrode formed through an insulating film in a groove having a first side surface adjacent to a source region and a base region, and a second conductive type first impurity region formed adjacent to a second side surface of the groove between the groove and a lead-out portion of a drain region existing below the base region so as to extend downward beyond a lower end of the groove.

Abstract: A method of manufacturing a semiconductor device including forming a first conductive-type buried layer in a substrate; forming a first conductive-type drift area on the first conductive-type buried layer; forming a gate insulating layer and gate electrodes by selectively removing the first conductive-type drift area; forming a first oxide layer on the substrate and gate electrodes; implanting second conductive-type impurity ions into the substrate; forming a nitride layer on the first oxide layer; forming a second conductive-type well by diffusing the second conductive-type impurity ions while forming a second oxide layer; removing the nitride layer, the second oxide layer, and portions of the first oxide layer; forming first conductive-type source areas at sides of the gate electrode(s); forming a dielectric layer on the oxide layer; forming a trench in the dielectric layer and the oxide layer; forming a source contact in the trench; and forming a drain.

Abstract: A method for forming a shielded gate field effect transistor includes the following steps. Trenches are formed in a semiconductor region of a first conductivity type. A shield electrode is formed in a bottom portion of each trench, the shield electrode being insulated from the semiconductor region by a shield dielectric. A gate electrode recessed in each trench is formed over the shield electrode, the gate electrode being insulated from the shield electrode. Using a first mask, a body region of a second conductivity type is formed in the semiconductor region by implanting dopants. Using the first mask, source regions of the first conductivity type are formed in the body region by implanting dopants.

Abstract: A semiconductor device and a method for making a semiconductor device are disclosed. A trench mask may be applied to a semiconductor substrate, which is etched to form trenches with three different widths. A first conductive material is formed at the bottom of the trenches. A second conductive material is formed over the first conductive material. An insulator layer separates the first and second conductive materials. A first insulator layer is deposited on top of the trenches. A body layer is formed in a top portion of the substrate. A source is formed in the body layer. A second insulator layer is applied on top of the trenches and the source. A contact mask is applied on top of the second insulator layer. Source and gate contacts are formed through the second insulator layer. Source and gate metal are formed on top of the second insulator layer.

Abstract: The invention includes methods of forming field effect transistors, methods of forming field effect transistor gates, methods of forming integrated circuitry comprising a transistor gate array and circuitry peripheral to the gate array, and methods of forming integrated circuitry comprising a transistor gate array including first gates and second grounded isolation gates. In one implementation, a method of forming a field effect transistor includes forming masking material over semiconductive material of a substrate. A trench is formed through the masking material and into the semiconductive material. Gate dielectric material is formed within the trench in the semiconductive material. Gate material is deposited within the trench in the masking material and within the trench in the semiconductive material over the gate dielectric material. Source/drain regions are formed. Other aspects and implementations are contemplated.

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: Methods of fabricating a super junction trench power MOSFET (metal oxide semiconductor field effect transistor) device are described. A column of p-type dopant in the super junction is separated from a first column of n-type dopant by a first column of oxide and from a second column of n-type dopant by a second column of oxide. In an n-channel device, a gate element for the FET is advantageously situated over the column of p-type dopant; and in a p-channel device, a gate element for the FET is advantageously situated over the column of n-type dopant.

Abstract: A semiconductor component that includes gate electrodes and shield electrodes and a method of manufacturing the semiconductor component. A semiconductor material has a device region, a gate contact region, a termination region, and a drain contact region. One or more device trenches is formed in the device region and one or more termination trenches is formed in the edge termination region. Shielding electrodes are formed in portions of the device trenches that are adjacent their floors. A gate dielectric material is formed on the sidewalls of the trenches in the device region and gate electrodes are formed over and electrically isolated from the shielding electrodes. The gate electrodes in the trenches in the device region are connected to the gate electrodes in the trenches in the gate contact region. The shielding electrodes in the trenches in the device region are connected to the shielding electrodes in the termination region.

Abstract: A method of manufacturing a semiconductor device including a buried insulating film formed in a bottom part of a trench and a buried-type gate electrode formed in the trench, the method including selectively forming an insulating film in the bottom part of the trench, forming a resist having an opening in a part that corresponds to a region where a device isolation insulating film is formed on a surface of a semiconductor substrate after forming the insulating film, and oxidizing the surface of the semiconductor substrate in the opening to form the device isolation insulating film.

Abstract: A trench MOSFET with copper metal connections includes a substrate provided with a plurality of trenches. A gate oxide layer is formed on the sidewalls and bottoms of the trenches. A conductive layer is filled in the trenches to be used as a gate of the MOSFET. A plurality of source and body regions are formed in an epi layer. An insulating layer is formed on the epi layer and formed with a plurality of metal contact holes therein for contacting respective source and body regions. A barrier metal layer is formed on the sidewalls and bottoms of the metal contact holes in direct contact with respective source and body regions. A metal contact layer is filled in the metal contact holes. A copper metal layer is formed on another barrier metal layer on the insulating layer connected to respective source regions through the metal contact layer to form metal connections of the MOSFET.

Abstract: A method for forming a semiconductor device includes forming a nanotube region using a thin epitaxial layer formed on the sidewall of a trench in the semiconductor body. The thin epitaxial layer has uniform doping concentration. In another embodiment, a first thin epitaxial layer of the same conductivity type as the semiconductor body is formed on the sidewall of a trench in the semiconductor body and a second thin epitaxial layer of the opposite conductivity type is formed on the first epitaxial layer. The first and second epitaxial layers have uniform doping concentration. The thickness and doping concentrations of the first and second epitaxial layers and the semiconductor body are selected to achieve charge balance. In one embodiment, the semiconductor body is a lightly doped P-type substrate. A vertical trench MOSFET, an IGBT, a Schottky diode and a P-N junction diode can be formed using the same N-Epi/P-Epi nanotube structure.

Abstract: Non-volatile memory devices and a method of manufacturing the same, wherein data storage of two bits per cell is enabled and the devices can pass the limit in terms of layout, whereby channel length can be controlled. The non-volatile memory device includes gate lines formed in one direction on a semiconductor substrate in which trenches are formed, wherein the gate lines gap-fill the trenches, a dielectric layer formed between the semiconductor substrate and the gate lines, bit separation insulating layers formed between the semiconductor substrate and the dielectric layer under the trenches, and isolation structures formed by etching the trenches, and the dielectric layer and the semiconductor substrate between the trenches in a line form vertical to the gate lines and gap-filling an insulating layer.

Abstract: A semiconductor device comprises a first conductive film formed downward, perpendicular to a substrate, penetrating through a first insulating film, a second conductive film formed downward along an outer wall of a second insulating film, a third insulating film formed from the bottom of the second conductive film to the top of the substrate in an area sandwiched between the first and second insulating films, contacting with at least the bottom of the second conductive film and an outer wall on a side which does not contact with the second insulating film, and a first impurity diffusion area of a first conductivity type, a second impurity diffusion area of a second conductivity type, a third impurity diffusion area of the first conductivity type and a fourth impurity diffusion area of the first conductivity type in a high concentration layered within the area sandwiched between the first and third insulating films.

Abstract: A semiconductor apparatus including a trench gate transistor having at least an active region surrounded by a device isolation insulating film; a trench provided by bringing both ends thereof into contact with the device isolation insulating film in the active region; a gate electrode formed in the trench via a gate insulating film; and a diffusion layer formed close to the trench; on a semiconductor substrate, and also includes an opening portion positioned on one surface of the semiconductor substrate; a pair of first inner walls positioned in a side of the device isolation insulating film and connected with the opening portion; a pair of second inner walls positioned in a side of the active region and connected with the opening portion; and a bottom portion positioned opposite to the opening portion and connected with the first inner walls and the second inner walls, wherein a cross sectional outline of the second inner wall is substantially linear, and a burr generated inside the trench is removed or redu

Abstract: A semiconductor device includes a substrate with a recess pattern, a gate electrode filling the recess pattern, a threshold voltage adjusting layer formed in the substrate under the recess pattern, a source/drain region formed in the substrate on both sides of the gate electrode and a gate insulation layer, with the recess pattern being disposed between the gate electrode and the substrate, wherein the thickness of the gate insulation layer formed in a region adjacent to the source/drain region is greater than the thickness of the gate insulation layer formed in a region adjacent to the threshold voltage adjusting layer.

Abstract: In accordance with an exemplary embodiment of the invention, a substrate of a first conductivity type silicon is provided. A substrate cap region of the first conductivity type silicon is formed such that a junction is formed between the substrate cap region and the substrate. A body region of a second conductivity type silicon is formed such that a junction is formed between the body region and the substrate cap region. A trench extending through at least the body region is then formed. A source region of the first conductivity type is then formed in an upper portion of the body region. An out-diffusion region of the first conductivity type is formed in a lower portion of the body region as a result of one or more temperature cycles such that a spacing between the source region and the out-diffusion region defines a channel length of the field effect transistor.

Abstract: A field effect transistor includes a plurality of trenches extending into a semiconductor region of a first conductivity type. The plurality of trenches include 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: A trench semiconductor device and a method of making the same are provided. The trench semiconductor device includes a trench MOS device and a trench ESD protection device. The trench ESD protection device is electrically connected between the gate electrode and source electrode of the trench MOS device so as to provide ESD protection. The fabrication of the ESD protection device is integrated into the process of the trench MOS device, and therefore no extra mask is required to define the doped regions of the trench ESD protection device. Consequently, the trench semiconductor device is advantageous for its simplified manufacturing process and low cost.