Abstract: A semiconductor device according to the present invention comprises a silicon carbide semiconductor substrate (1) including a silicon carbide layer (2); a high-concentration impurity region (4) provided in the silicon carbide layer (2); an ohmic electrode (9) electrically connected with the high-concentration impurity region (4); a channel region electrically connected with the high-concentration impurity region; a gate insulating layer (14) provided on the channel region; and a gate electrode (7) provided on the gate insulating layer (14). The ohmic electrode (9) contains an alloy of titanium, silicon and carbon, and the gate electrode (7) contains titanium silicide.

Abstract: A metal-oxide-semiconductor (MOS) device is disclosed. The MOS device includes a substrate of a first impurity type, a diffused region of a second impurity type in the substrate, a patterned first dielectric layer including a first dielectric portion over the diffused region, a patterned first conductive layer on the patterned first dielectric layer, the patterned first conductive layer including a first conductive portion on the first dielectric portion, a patterned second dielectric layer including a second dielectric portion that extends on a first portion of an upper surface of the first conductive portion and along a sidewall of the first conductive portion to the substrate; and a patterned second conductive layer on the patterned second dielectric layer, the patterned second conductive layer including a second conductive portion on the second dielectric portion.

Abstract: An MOS-bipolar hybrid-mode LDMOS device has a main gate input and a control gate input wherein the device operates in an MOS mode when both gate inputs are enabled, and operates in a bipolar mode when the main gate input is enabled and the control gate input is disabled. The device can drive the gate of a power MOSFET to deliver the high current required by the power MOSFET while in the bipolar mode, and provide a fully switching between supply voltage and ground to the gate of the power MOSFET while in the MOS mode.

Abstract: A laterally diffused metal-oxide-semiconductor device includes a substrate, a gate dielectric layer, a gate polysilicon layer, a source region, a drain region, a body region, a first drain contact plug, a source polysilicon layer, an insulating layer, and a source metal layer. The source polysilicon layer disposed on the gate dielectric layer above the drain region can serve as a field plate to enhance the breakdown voltage and to increase the drain-to-source capacitance. In addition, the first drain contact plug of the present invention can reduce the drain-to-source on-resistance and the horizontal extension length.

Abstract: An integrated circuit device and method for fabricating the integrated circuit device is disclosed. In an embodiment, an apparatus includes a substrate having a first surface and a second surface, the second surface being opposite the first surface; a first device and a second device overlying the substrate; and an isolation structure that extends through the substrate from the first surface to the second surface and between the first device and the second device.

Abstract: A transistor is formed inside an isolation structure which includes a floor isolation region and a trench extending from the surface of the substrate to the floor isolation region. The trench may be filled with a dielectric material or may have a conductive material in a central portion with a dielectric layer lining the walls of the trench.

Abstract: A power supply capable of reducing loss of large current and high frequency. In an MCM for power supply in which a high-side power MOSFET chip, a low-side power MOSFET chip and a driver IC chip driving them are sealed in one sealing material (a capsulating insulation resin), a wiring length of a wiring DL connecting an output terminal of the driver IC chip to a gate terminal of the low-side power MOSFET chip or a source terminal is made shorter than a wiring length of a wiring DH connecting the output terminal of the driver IC chip to a gate terminal of the high-side power MOSFET chip or a source terminal. Further, the number of the wiring DL is made larger than the number of the wiring DH.

Abstract: To reduce the size and improve the power added efficiency of an RF power module having an amplifier element composed of a silicon power MOSFET, the on resistance and feedback capacitance, which were conventionally in a trade-off relationship, are reduced simultaneously by forming the structure of an offset drain region existing between a gate electrode and an n+ type drain region of the power MOSFET into a double offset one. More specifically, this is accomplished by adjusting the impurity concentration of an n? type offset drain region, which is closest to the gate electrode, to be relatively low and adjusting the impurity concentration of an n type offset drain region, which is distant from the gate electrode, to be relatively high.

Abstract: A semiconductor integrated circuit device and method of fabricating a semiconductor integrated circuit device, the method including preparing a first conductivity type substrate including a first conductivity type impurity such that the first conductivity type substrate has a first impurity concentration; forming a buried impurity layer using blank implant such that the buried impurity layer includes a first conductivity type impurity and has a second impurity concentration higher than the first impurity concentration; forming an epitaxial layer on the substrate having the buried impurity layer thereon; and forming semiconductor devices and a device isolation region in or on the epitaxial layer.

Abstract: A transistor includes a source region including a first impurity region implanted into a substrate, a drain region including a second impurity region implanted into the substrate, and a gate including an oxide layer formed over the substrate and a conductive material formed over the oxide layer, the oxide layer comprising a first side and a second side, the first side formed over a portion of the first impurity region and the second side formed over a portion of the second impurity region, the first side having a thickness of less than about 100 ?, and the second side having a thickness equal to or greater than 125 ?.

Abstract: In a self protected NLDMOS array, a deep implant is included on the drain side of each NLDMOS device to balance ESD current.

Abstract: Provided are a semiconductor device and a method of fabricating the semiconductor device. The semiconductor device can provide a trench MOS transistor having an up-drain structure. The semiconductor device can include a first conductive type well in a semiconductor substrate, a second conductive type well on the first conductive type well, trenches formed by removing portions of the second conductive type well and the first conductive type well; gates provided in the trenches with a gate dielectric being between each gate and the walls of the trench, a first conductive type source region and a second conductive type body region on the second conductive type well, the first conductive type source region surrounding a lateral surface of the gate, and a common drain between the gates, the common drain being connected to the first conductive type well.

Abstract: The present invention discloses an LDMOS device having an increased punch-through voltage and a method for making same. The LDMOS device includes: a substrate; a well of a first conductive type formed in the substrate; an isolation region formed in the substrate; a body region of a second conductive type in the well; a source in the body region; a drain in the well; a gate structure on the substrate; and a first conductive type dopant region beneath the body region, for increasing a punch-through voltage.

Abstract: Vertical capacitive depletion field effect transistors (VCDFETs) and methods for fabricating VCDFETs are disclosed. An example VCDFET includes one or more interleaved drift and gate regions. The gate region(s) may be configured to capacitively deplete the drift region(s) though one or more insulators that separate the gate region(s) from the drift region(s). The drift region(s) may have graded/non-uniform doping profiles. In addition, one or more ohmic and/or Schottky contacts may be configured to couple one or more source electrodes to the drift region(s).

Abstract: A semiconductor device includes a semiconductor substrate, a first p-channel laterally diffused metal oxide semiconductor (LDMOS) transistor formed over the semiconductor substrate and additional p-channel LDMOS transistors formed over the semiconductor substrate. First drain and gate electrodes are formed over the substrate and are coupled to the first LDMOS transistor. Additional drain and gate electrodes are formed over the substrate and are coupled to the second LDMOS transistor. A common source electrode for the first and second LDMOS transistors is also formed over the substrate.

Abstract: A semiconductor device eg. a MOSFET (1) comprising a substrate (40) including a first region (18) and a second region (16) of a first conductivity type and a third region (42) between the first and second regions of a type opposite to the first conductivity type, and being covered by a dielectric layer (20), a plurality of trenches (12) laterally extending between the third and second region, said trenches being filled with an insulating material, and being separated by active stripes (14) comprising a doping profile having a depth not exceeding the depth of the trenches wherein each trench terminates before reaching the dielectric layer (20),namely is separated from the third region by a substrate portion (26) such that the respective boundaries between the substrate portions and the trenches are not covered by the dielectric layer. A method for manufacturing such a semiconductor device is also disclosed.

Abstract: An electronic device can include a buried conductive region, a buried insulating layer over the buried conductive region, and a semiconductor layer disposed over the buried insulating layer, wherein the semiconductor layer has a primary surface and an opposing surface, and the buried conductive region is disposed closer to the opposing surface than to the primary surface. The electronic device can also include a current-carrying electrode of a first transistor, wherein the current carrying electrode is disposed along the primary surface and spaced apart from the buried conductive layer. The electronic device can also include a vertical conductive structure extending through the buried insulating layer, wherein the vertical conductive structure is electrically connected to the current-carrying electrode and the buried conductive region.

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: An integrated circuit having an SCRMOS transistor with a RESURF region around the drain region and SCR terminal. The RESURF region is the same conductivity type as the drift region and is more heavily doped than the drift region. An SCRMOS transistor with a RESURF region around the drain region and SCR terminal. A process of forming an integrated circuit having an SCRMOS transistor with a RESURF region around the drain region and SCR terminal.

Abstract: In a high frequency amplifying MOSFET having a drain offset region, the size is reduced and the on-resistance is decreased by providing conductor plugs 13 (P1) for leading out electrodes on a source region 10, a drain region 9 and leach-through layers 3 (4), to which a first layer wirings 11a, 11d (M1) are connected and, further, backing second layer wirings 12a to 12d are connected on the conductor plugs 13 (P1) to the first layer wirings 11s, 11d (M1).

Abstract: According to one embodiment, a semiconductor device having an overlapping multi-well implant comprises an isolation structure formed in a semiconductor body, a first well implant formed in the semiconductor body surrounding the isolation structure, and a second well implant overlapping at least a portion of the first well implant. The disclosed semiconductor device, which may be an NMOS or PMOS device, can further comprise a gate formed over the semiconductor body adjacent to the isolation structure, wherein the first well implant extends a first lateral distance under the gate and the second well implant extends a second lateral distance under the gate, and wherein the first and second lateral distances may be different. In one embodiment, the disclosed semiconductor device is fabricated as part of an integrated circuit including a power management circuit or a power amplifier.

Abstract: An LDMOS device includes a substrate of a first conductivity type, an epitaxial layer on the substrate, a buried well of a second conductivity type opposite to the first conductivity type in a lower portion of the epitaxial layer, the epitaxial layer being of the first conductivity type below the buried layer. The device further includes a field oxide located between a drain and both a gate on a gate oxide and a source with a saddle shaped vertical doping gradient of the second conductivity type in the epitaxial layer above the buried well such that the dopant concentration in the epitaxial layer above the buried well and below a central portion of the field oxide is lower than the dopant concentration at the edges of the field oxide nearest the drain and nearest the gate.

Abstract: A high voltage (HV) device includes a well region of a first dopant type disposed in a substrate. A first well region of a second dopant type is disposed in the well region of the first dopant type. An isolation structure is at least partially disposed in the well region of the first dopant type. A first gate electrode is disposed over the isolation structure and the first well region of the second dopant type. A second well region of the second dopant type is disposed in the well region of the first dopant type. The second well region of the second dopant type is spaced from the first well region of the second dopant type. A second gate electrode is disposed between and over the first well region of the second dopant type and the second well region of the second dopant type.

Abstract: A semiconductor device includes a substrate having a first region and a second region. The first region is electrically isolated from the second region. The semiconductor device further includes a lateral field-effect transistor (FET) disposed within the first region. The lateral FET includes a first terminal and a second terminal. The semiconductor device further includes a diode disposed within the second region, the diode including a plurality of anode regions and a plurality of cathode regions. The semiconductor device further includes a first electrical connection between the first terminal of the lateral FET and the anode regions of the diode, and a second electrical connection between the second terminal of the lateral FET and the cathode regions of the diode. The first and second electrical connections are disposed over a surface of the substrate.

Abstract: A semiconductor integrated circuit device may include: a substrate that includes a high-voltage device region and a low-voltage device region defined on the substrate; a first buried impurity layer formed in at least a portion of the high-voltage device region and coupled to a first voltage; a second buried impurity layer formed in at least a portion of the low-voltage device region and coupled to a second voltage less than the first voltage; and a well formed on the second buried impurity layer in the low-voltage device region and coupled to a third voltage less than the second voltage.

Abstract: A power device with improved reliability and a method for producing the same is disclosed. One embodiment provides an active area having an electrical power dissipation characteristic, a metallization layer portion configured with respect to the active area so that the dissipation characteristic of the active area results in heating the metallization layer portion, the metallization layer portion being formed as a connected region. The metallization layer portion has at least one hole, fully extending through the metal layer and having a dielectric. The at least one hole is arranged so that each location of the metal layer portion is connected electrically to each other location via the metallization material of the metal layer portion.

Abstract: An integrated circuit structure includes a semiconductor substrate and a high-voltage metal-oxide-semiconductor (HVMOS) device, which includes a first high-voltage well (HVW) region of a first conductivity type in the semiconductor substrate; a drain region of a second conductivity type opposite the first conductivity type in the semiconductor substrate and spaced apart from the first HVW region; a gate dielectric with at least a portion directly over the first HVW region; and a gate electrode over the gate dielectric. The gate dielectric includes a bottom gate oxide region; and a silicon nitride region over the bottom gate oxide region.

Abstract: This invention discloses configurations and methods to manufacture lateral power device including a super junction structure with an avalanche clamp diode formed between the drain and the gate. The lateral super-junction structure reduces on-resistance, while the structural enhancements, including an avalanche clamping diode and an N buffer region, increase the breakdown voltage between substrate and drain and improve unclamped inductive switching (UIS) performance.

Abstract: A semiconductor device includes a substrate with one or more active regions and an isolation layer formed to surround an active region and to extend deeper into the substrate than the one or more active regions. The semiconductor further includes a gate electrode, which covers a portion of the active region, and which has one end ;portion thereof extending over the isolation layer.

Abstract: An integrated circuit containing an MOS transistor with a trenched gate abutting an isolation dielectric layer over a drift region. The body well and source diffused region overlap the bottom surface of the gate trench. An integrated circuit containing an MOS transistor with a first trenched gate abutting an isolation dielectric layer over a drift region, and a second trenched gate located over a heavily doped buried layer. The buried layer is the same conductivity type as the drift region. A process of forming an integrated circuit containing an MOS transistor, which includes an isolation dielectric layer over a drift region of a drain of the transistor, and a gate formed in a gate trench which abuts the isolation dielectric layer. The gate trench is formed by removing substrate material adjacent to the isolation dielectric layer.

Abstract: A semiconductor device and method is disclosed. One embodiment provides an active region in a semiconductor substrate, including a first terminal region and a second terminal region.

Abstract: A field effect transistor semiconductor device configuration is described, which is particularly suitable for use in DC: DC converters associated with logic circuitry. The device includes a first gate electrode (18) which extends adjacent to its channel-accommodating region (14) and a second, dummy gate electrode (30) which extends adjacent to the drain drift region (12). The second gate electrode is electrically connected to the first gate electrode and serves to reduce the on-resistance of the device and improve its reliability by reducing hot carrier degradation.

Abstract: A semiconductor device includes: a SOI substrate; a semiconductor element having first and second impurity layers disposed in an active layer of the SOI substrate, the second impurity layer surrounding the first impurity layer; and multiple first and second conductive type regions disposed in a part of the active layer adjacent to an embedded insulation film of the SOI substrate. The first and second conductive type regions are alternately arranged. The first and second conductive type regions have a layout, which corresponds to the semiconductor element.

Abstract: According to one embodiment, a semiconductor device includes: a substrate in which, on a semiconductor substrate of a first conductivity type, a buried layer of a second conductivity type and a semiconductor layer of the second conductivity type are stacked; trench that define an element forming region in the substrate; element isolation insulation film formed in the trench; and a semiconductor element formed in the element forming region. The trench include first trench formed from the surface of the substrate to boundary depth and second trench formed from the boundary depth to the bottom and having a diameter smaller than that of the first trench. First diffusion layers connected to the buried layer are formed around the first or second trench according to inter-element breakdown voltage required of the semiconductor element.

Abstract: A method of manufacturing a semiconductor device is provided which comprises: forming a first gate insulating film and a second gate insulating film in an active region of a semiconductor substrate; introducing an impurity of a first conductivity type into a first site where a first body region is to be formed, the first site being disposed under the first gate insulating film in the active region; forming a gate electrode on each of the first gate insulating film and the second gate insulating film; and introducing an impurity of the first conductivity type into the first site and a second site where a second body region is to be formed, the second site being disposed under the second gate insulating film in the active region, to form the first body region and the second body region, respectively.

Abstract: An IGBT includes a first region, a second region located within the first region, a first contact coupled to the first region, a first layer arranged below the first region, a gate overlying at least a portion of the first region between the second region and the first layer and a second layer formed under the first layer. One or more stacked zones are formed within the second layer. Each one or more stacked zones includes a first zone and a second zone that overlies the first zone. Each first zone is inversely doped with respect to the second layer and each second zone is inversely doped with respect to the first zone. The IGBT further includes a third layer formed under the second layer and a second contact coupled to the third layer.

Abstract: According to one embodiment, a semiconductor device includes: a semiconductor substrate of a first conductivity type; a source region; a drain region of a second conductivity type; a gate electrode formed via a gate insulating film on the semiconductor substrate between the source region and the drain region; and a drift region of the second conductivity type formed adjacent to the drain region from the drain region to a lower part of the gate electrode. The upper surface of the gate electrode is formed such that the height of a side on the source region side of a stack of the gate electrode and the gate insulating film is larger than the height of a side on the drain region side of the stack.

Abstract: A semiconductor device including a substrate, an epitaxial layer, a first sinker, a transistor, a diode unit, a first buried layer, and a second buried layer is provided. When the semiconductor device is operated at the high voltage, the highly large substrate current due to the external load is avoided through the diode unit disposed in the semiconductor device of an embodiment consistent with the invention. Furthermore, according to the design of the semiconductor device, the issue of the narrow input voltage range is improved, and interference of the semiconductor device with the other semiconductor devices is prevented.

Abstract: An integrated circuit with a transistor advantageously embodied in a laterally diffused metal oxide semiconductor device having a gate located over a channel region recessed into a semiconductor substrate and a method of forming the same. In one embodiment, the transistor includes a source/drain including a lightly or heavily doped region adjacent the channel region, and an oppositely doped well extending under the channel region and a portion of the lightly or heavily doped region of the source/drain. The transistor also includes a channel extension, within the oppositely doped well, under the channel region and extending under a portion of the lightly or heavily doped region of the source/drain.

Abstract: A semiconductor device has an insulating film and an n-type buried layer. The insulating film is formed in a flat-shaped cavity formed inside a p-type semiconductor substrate and in a trench extending from a surface of the semiconductor substrate to the cavity. The buried layer is formed in surrounding regions of the cavity and the trench in the semiconductor substrate.

Abstract: A MOS device includes a semiconductor substrate having a first conductive type, a source region, a gate structure, and a drain region having a second conductive type. The gate structure is formed on the semiconductor substrate and substantially parallel to a first direction. The source region and the drain region are both disposed in the semiconductor substrate, and on two opposite sides of the gate structure. The source region includes at least a source doped region having the second conductive type, and at least a source contact region having the first conductive type, and the source doped region and the source contact region are alternately arranged along the first direction.

Abstract: A semiconductor fabrication process according to the present invention defines an auxiliary structure with a plurality of spaces with a predetermined line-width in the oxide layer to prevent the conductive material in the spaces from being removed by etching or defined an auxiliary structure to rise the conductive structure so as to have the conductive structure being exposed by chemical mechanical polishing. Thus, the transmitting circuit can be defined without requiring an additional mask. Hence, the semiconductor fabrication process can reduce the number of required masks to lower the cost.

Abstract: An I/O electrostatic discharge (ESD) device having a gate electrode over a substrate, a gate dielectric layer between the gate electrode and the substrate, a pair of sidewall spacers respectively disposed on two opposite sidewalls of the gate electrode, a first lightly doped drain (LDD) region disposed under one of the sidewall spacers, a source region disposed next to the first LDD region, a second LDD region disposed under the other sidewall spacer, and a drain region disposed next to the second LDD region, wherein a doping concentration of the second LDD region is larger than a doping concentration of the first LDD region.

Abstract: A semiconductor structure including a substrate, at least one power MOSFET, a floating diode or a body diode, and at least one Schottky diode is provided. The substrate has a first area, a second area and a third area. The second area is between the first area and the third area. The at least one power MOSFET is in the first area. The floating diode or the body diode is in the second area. The at least one Schottky diode is in the third area. Further, the contact plugs of the power MOSFET and the Schottky diode include tungsten and are electronically connected to each other.

Abstract: There is provided a high withstand voltage LDMOS which is a MOS transistor formed on a semiconductor substrate and isolated by a trench, and a source region of which is sandwiched by a drain region, in which the metal layer gate wire connected to the gate electrode is led out outside the trench so as to pass over a P-type drift layer.

Abstract: An integrated circuit (IC) device including a substrate, a plurality of device layers formed over the substrate, and a plurality of multi-level revision (MLR) structures that generate a revision code indicative of device revisions. Each MLR group structure includes a number of MLR cells and includes a parity circuit having a number of inputs coupled to the outputs of the MLR cells and having an output to generate a corresponding bit of the revision code. The MLR cells in each MLR group structure are assigned to different device layers, and each device layer is assigned to one MLR cell in each MLR group structure. Each revision code bit is controllable by any MLR cell in the corresponding MLR group structure.

Abstract: A power semiconductor component includes a drift zone in a semiconductor body, a component junction and a compensation zone. The component junction is disposed between the drift zone and a further component zone, which is configured such that when a blocking voltage is applied to the component junction, a space charge zone forms extending generally in a first direction in the drift zone. The compensation zone is disposed adjacent to the drift zone in a second direction and includes at least one high-dielectric material having a temperature-dependent dielectric constant. The temperature dependence of the compensation zone varies in the second direction.

Abstract: A non-insulated DC-DC converter has a power MOS•FET for a highside switch and a power MOS•FET for a lowside switch. In the non-insulated DC-DC converter, the power MOS•FET for the highside switch and the power MOS•FET for the lowside switch, driver circuits that control operations of these elements, respectively, and a Schottky barrier diode connected in parallel with the power MOS•FET for the lowside switch are respectively formed in four different semiconductor chips. These four semiconductor chips are housed in one package. The semiconductor chips are mounted over the same die pad. The semiconductor chips are disposed so as to approach each other.

Abstract: In a lateral-type power MOSFET, high breakdown voltage is achieved with suppressing to increase a cell pitch, and a feedback capacity and an ON resistance are decreased. An n? type silicon region having a high resistance to be a region of maintaining a breakdown voltage is vertically provided with respect to a main surface of an n+ type silicon substrate, and the n? type silicon region having the high resistance is connected to the n+ type silicon substrate. Also, a conductive substance is filled through an insulating substance inside a trench formed to reach the n+ type silicon substrate from the main surface of the n+ type silicon substrate so as to contact with the n? type silicon region having the high resistance, and the conductive substance is electrically connected to a source electrode.

Abstract: Disclosed is a transistor component having a control structure with a channel control layer of an amorphous semiconductor insulating material extending in a current flow direction along a channel zone.