Abstract: A mask used to form an n+ source layer (11) is formed by a nitride film on the surface of a substrate before a trench (7) is formed. At this time, a sufficient width of the n+ source layer (11) on the surface of the substrate is secured. Thereby, stable contact between the n+ source layer (11) and a source electrode (15) is obtained. A CVD oxide film (12) that is an interlayer insulating film having a thickness of 0.1 micrometer or more and 0.3 micrometer or less is formed on doped poly-silicon to be used as a gate electrode (10a) embedded in the trench (7), and non-doped poly-silicon (13) that is not oxidized is formed on the CVD oxide film (12). Thereby, generation of void in the CVD oxide film (12) is suppressed and, by not oxidizing the non-doped poly-silicon (13), a semiconductor apparatus is easily manufactured.

Abstract: According to one embodiment, a semiconductor device includes a semiconductor layer including Ge; and a metal Ge compound region provided in a surface portion of the semiconductor layer. Sn is included in an interface portion between the semiconductor layer and the metal Ge compound region. A lattice plane of the semiconductor layer matches with a lattice plane of the metal Ge compound region.

Abstract: In a semiconductor device such as a three-phase one-chip gate driver IC, HVNMOSs configuring two set and reset level shift circuits are disposed on non-opposed surfaces, and it is thereby possible to reduce the amount of electrons flowing into drains of HVNMOSs of another phase due to a negative voltage surge. Also, distances from an opposed surface on the opposite side to the respective drains of the HVNMOSs configuring the two set and reset level shift circuits are made equal to or more than 150 ?m, and it is thereby possible to prevent a malfunction of a high side driver circuit of another phase to which no negative surge is applied.

Abstract: A semiconductor device includes a semiconductor substrate including a well dopant layer having a first conductivity type, a gate electrode on the well dopant layer, a channel dopant layer in the well dopant layer and spaced apart from a top surface of the semiconductor substrate, a channel region between the gate electrode and the channel dopant layer, and source/drain regions in the well dopant layer at both sides of the gate electrode. The channel dopant layer and the channel region have the first conductivity type. The source/drain regions have a second conductivity type. A concentration of dopants having the first conductivity type in the channel dopant layer is higher than a concentration of dopants having the first conductivity type in the channel region. The semiconductor device may be used in a sense amplifier of a memory device.

Abstract: A manufacturing method of a semiconductor device including a DMOS transistor, an NMOS transistor and a PMOS transistor arranged on a semiconductor substrate, the DMOS transistor including a first impurity region and a second impurity region formed to be adjacent to each other, the first impurity region being of the same conductivity type as a drain region and a source region of the DMOS transistor, forming to enclose the drain region, and the second impurity region being of a conductivity type opposite to the first impurity region, forming to enclose the source region, the manufacturing method of the semiconductor device comprising forming the first impurity region and one of the NMOS transistor and the PMOS transistor, and forming the second impurity region and the other of the NMOS transistor and the PMOS transistor.

Abstract: A semiconductor device includes a P-channel DMOS transistor provided with an N-type gate electrode, a P-channel MOS transistor provided with a P-type gate electrode, and an N-channel MOS transistor provided with an N-type gate electrode. The N-type gate electrode of the P-channel DMOS transistor desirably has a first end portion that is located on a source side of the P-channel DMOS transistor, a second end portion that is located on a drain side of the P-channel DMOS transistor, and a P-type diffusion layer at the first end portion.

Abstract: Among other things, an electrostatic discharge (ESD) device is provided. The ESD device comprises a dielectric isolation structure that is formed between an emitter and a collector of the ESD device. During an ESD event, current flows from the emitter, substantially under the dielectric isolation structure, to the collector, to protect associated circuitry. The dielectric isolation structure is formed to a depth that is less than a depth of at least one of the emitter or the collector, or doped regions thereof, thereby decreasing a length of a current path from the emitter to the collector, because the current is not obstructed by the dielectric isolation structure. Accordingly, the ESD device can carry higher current during the ESD event because the shorter current path has less resistance than a longer path that would otherwise be traveled if the dielectric isolation structure was not formed at the shallower depth.

Abstract: Various embodiments provide multi-gate VDMOS transistors. The transistor can include a substrate having a first surface and a second surface opposite to the first surface, a drift layer on the first surface of the substrate, and an epitaxial layer on the drift layer. The transistor can further include a plurality of trenches. Each trench can pass through the epitaxial layer and a thickness portion of the drift layer. The transistor can further include a plurality of gate structures. Each gate structure can fill the each trench. The transistor can further include a plurality of doped regions in the epitaxial layer. Each doped region can surround a sidewall of the each gate structure. The transistor can further include a source metal layer on the epitaxial layer to electrically connecting the plurality of doped regions, and a drain metal layer on the second surface of the substrate.

Abstract: A gate cavity is formed exposing a portion of a silicon fin by removing a sacrificial gate structure that straddles the silicon fin. An epitaxial silicon germanium alloy layer is formed within the gate cavity and on the exposed portion of the silicon fin. Thermal mixing or thermal condensation is performed to convert the exposed portion of the silicon fin into a silicon germanium alloy channel portion which is laterally surrounded by silicon fin portions. A functional gate structure is formed within the gate cavity providing a finFET structure having a silicon germanium alloy channel portion which is laterally surrounded by silicon fin portions.

Abstract: Electronic circuits and methods are provided for various applications including signal amplification. An exemplary electronic circuit comprises a MOSFET and a dual-gate JFET in a cascode configuration. The dual-gate JFET includes top and bottom gates disposed above and below the channel. The top gate of the JFET is controlled by a signal that is dependent upon the signal controlling the gate of the MOSFET. The control of the bottom gate of the JFET can be dependent or independent of the control of the top gate. The MOSFET and JFET can be implemented as separate components on the same substrate with different dimensions such as gate widths.

Abstract: A method includes forming a layer of silicon-carbon on an N-active region, performing a common deposition process to form a layer of a first semiconductor material on the layer of silicon-carbon and on the P-active region, masking the N-active region, forming a layer of a second semiconductor material on the first semiconductor material in the P-active region and forming N-type and P-type transistors. A device includes a layer of silicon-carbon positioned on an N-active region, a first layer of a first semiconductor positioned on the layer of silicon-carbon, a second layer of the first semiconductor material positioned on a P-active region, a layer of a second semiconductor material positioned on the second layer of the first semiconductor material, and N-type and P-type transistors.

Abstract: A MOS transistor includes a p-type semiconductor substrate, a p-type epitaxial layer, and an n-type buried layer provided in a boundary between the semiconductor substrate and the epitaxial layer. In a p-type body layer provided in a surface portion of the epitaxial layer, an n-type source layer is provided to define a double diffusion structure together with the p-type body layer. An n-type drift layer is provided in a surface portion of the epitaxial layer in spaced relation from the body layer. An n-type drain layer is provided in a surface portion of the epitaxial layer in contact with the n-type drift layer. A p-type buried layer having a lower impurity concentration than the n-type buried layer is buried in the epitaxial layer between the drift layer and the n-type buried layer in contact with an upper surface of the n-type buried layer.

Abstract: Embodiments of semiconductor devices and driver circuits include a semiconductor substrate having a first conductivity type, an isolation structure (including a sinker region and a buried layer), an active device within area of the substrate contained by the isolation structure, and a diode circuit. The buried layer is positioned below the top substrate surface, and has a second conductivity type. The sinker region extends between the top substrate surface and the buried layer, and has the second conductivity type. The active device includes a source region of the first conductivity type, and the diode circuit is connected between the isolation structure and the source region. The diode circuit may include one or more Schottky diodes and/or PN junction diodes. In further embodiments, the diode circuit may include one or more resistive networks in series and/or parallel with the Schottky and/or PN diode(s).

Abstract: Various embodiments provide multi-gate VDMOS transistors. The transistor can include a substrate having a first surface and a second surface opposite to the first surface, a drift layer on the first surface of the substrate, and an epitaxial layer on the drift layer. The transistor can further include a plurality of trenches. Each trench can pass through the epitaxial layer and a thickness portion of the drift layer. The transistor can further include a plurality of gate structures. Each gate structure can fill the each trench. The transistor can further include a plurality of doped regions in the epitaxial layer. Each doped region can surround a sidewall of the each gate structure. The transistor can further include a source metal layer on the epitaxial layer to electrically connecting the plurality of doped regions, and a drain metal layer on the second surface of the substrate.

Abstract: A lateral semiconductor device including a semiconductor substrate; a buried oxide layer formed on the semiconductor substrate, and an active layer formed on the buried oxide layer. The active layer includes a first conductivity type well region, a second conductivity type well region, and a first conductivity type drift region interposed between the first conductivity type well region and the second conductivity type well region. A region where current flows because of carriers moving between the first conductivity type well region and the second conductivity type well region, and a region where no current flows are formed alternately between the first conductivity type well region and the second conductivity type well region, in a direction perpendicular to a carrier moving direction when viewed in a plan view.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate, and first and second transistors of first and second conductivity types on the substrate. The first transistor includes a first gate electrode on the substrate, a first source region of the second conductivity type and a first drain region of the first conductivity type disposed to sandwich the first gate electrode, and a first channel region of the first or second conductivity type disposed between the first source region and the first drain region. The second transistor includes a second gate electrode on the substrate, a second source region of the first conductivity type and a second drain region of the second conductivity type disposed to sandwich the second gate electrode, and a second channel region disposed between the second source region and the second drain region and having the same conductivity type as the first channel region.

Abstract: In one embodiment, the present invention includes a method for forming a logic device, including forming an n-type semiconductor device over a silicon (Si) substrate that includes an indium gallium arsenide (InGaAs)-based stack including a first buffer layer, a second buffer layer formed over the first buffer layer, a first device layer formed over the second buffer layer. Further, the method may include forming a p-type semiconductor device over the Si substrate from the InGaAs-based stack and forming an isolation between the n-type semiconductor device and the p-type semiconductor device. Other embodiments are described and claimed.

Abstract: A super-junction device including a unit region is disclosed. The unit region includes a heavily doped substrate; a first epitaxial layer over the heavily doped substrate; a second epitaxial layer over the first epitaxial layer; a plurality of first trenches in the second epitaxial layer; an oxide film in each of the plurality of first trenches; and a pair of first films on both sides of each of the plurality of first trenches, thereby forming a sandwich structure between every two adjacent ones of the plurality of first trenches, the sandwich structure including two first films and a second film sandwiched therebetween, the second film being formed of a portion of the second epitaxial layer between the two first films of a sandwich structure. A method of forming a super-junction device is also disclosed.

Abstract: A semiconductor structure for facilitating an integration of power devices on a common substrate includes a first insulating layer formed on the substrate and an active region having a first conductivity type formed on at least a portion of the first insulating layer. A first terminal is formed on an upper surface of the structure and electrically connects with at least one other region having the first conductivity type formed in the active region. A buried well having a second conductivity type is formed in the active region and is coupled with a second terminal formed on the upper surface of the structure. The buried well and the active region form a clamping diode which positions a breakdown avalanche region between the buried well and the first terminal. A breakdown voltage of at least one of the power devices is a function of characteristics of the buried well.

Abstract: The present invention relates to a technique of semiconductor devices, and provides a semiconductor device, which uses two controllable current sources to control the electron current and the hole current of the voltage-sustaining region of a thyristor under conduction state, making the sum of the two currents from anode to cathode close to a saturated value under high voltage, thus avoiding the current crowding effect in local region and increasing the reliability of the device. Besides, it further provides a method of implementing the two current sources in the device and a method to improve the switching speed.

Abstract: A semiconductor device includes: first and second n-type wells formed in p-type semiconductor substrate, the second n-type well being deeper than the first n-type well; first and second p-type backgate regions formed in the first and second n-type wells; first and second n-type source regions formed in the first and second p-type backgate regions; first and second n-type drain regions formed in the first and second n-type wells, at positions opposed to the first and second n-type source regions, sandwiching the first and the second p-type backgate regions; and field insulation films formed on the substrate, at positions between the first and second p-type backgate regions and the first and second n-type drain regions; whereby first transistor is formed in the first n-type well, and second transistor is formed in the second n-type well with a higher reverse voltage durability than the first transistor.

Abstract: According to one embodiment, a one-time programmable (OTP) device having a lateral diffused metal-oxide-semiconductor (LDMOS) structure comprises a pass gate including a pass gate electrode and a pass gate dielectric, and a programming gate including a programming gate electrode and a programming gate dielectric. The programming gate is spaced from the pass gate by a drain extension region of the LDMOS structure. The LDMOS structure provides protection for the pass gate when a programming voltage for rupturing the programming gate dielectric is applied to the programming gate electrode. A method for producing such an OTP device comprises forming a drain extension region, fabricating a pass gate over a first portion of the drain extension region, and fabricating a programming gate over a second portion of the drain extension region.

Abstract: A HKMG device with PMOS eSiGe source/drain regions is provided. Embodiments include forming first and second HKMG gate stacks on a substrate, forming a nitride liner and oxide spacers on each side of each HKMG gate stack, performing halo/extension implants at each side of each HKMG gate stack, forming an oxide liner and nitride spacers on the oxide spacers of each HKMG gate stack, forming deep source/drain regions at opposite sides of the second HKMG gate stack, forming an oxide hardmask over the second HKMG gate stack, forming embedded silicon germanium (eSiGe) at opposite sides of the first HKMG gate stack, and removing the oxide hardmask.

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: A device includes a first transistor including a first gate electrode including first and second parallel electrode portions each extending in a first direction, and a first connecting electrode portion extending in a second direction approximately orthogonal to the first direction and connecting one ends of the first and second parallel electrode portions to each other, and first and second diffusion layers separated from each other by a channel region under the first gate electrode, a first output line connected to the first diffusion layer of the first transistor, and a second transistor comprising a second gate electrode extending in the second direction, and the second transistor being configured to use the second diffusion layer of the first transistor as one of two diffusion layers that are separated from each other by a channel region under the second gate electrode.

Abstract: A semiconductor integrated circuit device has a p-type substrate to which a ground voltage is applied and a floating-type NMOSFET which is integrated on the p-type substrate and to which a negative voltage lower than the ground voltage is applied. The floating-type NMOSFET includes an n-type buried layer buried in the p-type substrate, a high voltage n-type well formed on the n-type buried layer and floats electrically, a p-type drift region formed in the n-type well, an n-type drain region and an-type source region formed in the p-type drift region, and a gate electrode formed on a channel region interposed between the n-type drain region and the n-type source region. The high voltage n-type well includes an n-type tunnel region, with a higher impurity concentration than that of the high voltage n-type well, inside a peripheral region formed so as to surround the p-type drift region.

Abstract: An inventive semiconductor device includes a semiconductor layer, a source region provided in a surface layer portion of the semiconductor layer, a drain region provided in the surface of the semiconductor layer in spaced relation from the source region, a gate insulation film provided in opposed relation to a portion of the surface of the semiconductor layer present between the source region and the drain region, a gate electrode provided on the gate insulation film, and a drain-gate isolation portion provided between the drain region and the gate insulation film for isolating the drain region and the gate insulation film from each other in non-contact relation.

Abstract: The present invention relates to a switch circuit, and more particularly, to a switch circuit that uses an LDMOS (lateral diffusion metal oxide semiconductor) device inside an IC (Integrated Circuit). In the switch circuit that uses the LDMOS device according to an embodiment of the present invention, a gate-source voltage (VGS) of the LDMOS device may be stably controlled through a current source and resistances, the characteristics of a switch may be maintained regardless of the voltages of both terminals (A and B) by using an N-type LDMOS and a P-type LDMOS in a complementary manner, and the current generated by the current source is offset inside the switch without flowing to the outside of the switch.

Abstract: Silicon germanium regions are formed adjacent gates electrodes over both n-type and p-type regions in an integrated circuit. A hard mask patterned by lithography then protects structures over the p-type region while the silicon germanium is selectively removed from over the n-type region, even under remnants of the hard mask on sidewall spacers on the gate electrode. Silicon germanium carbon is epitaxially grown adjacent the gate electrode in place of the removed silicon germanium, and source/drain extension implants are performed prior to removal of the remaining hard mask over the p-type region structures.

Abstract: A semiconductor structure and methods for forming the same are provided. The semiconductor structure includes a first MOS device of a first conductivity type and a second MOS device of a second conductivity type opposite the first conductivity type. The first MOS device includes a first gate dielectric on a semiconductor substrate; a first metal-containing gate electrode layer over the first gate dielectric; and a silicide layer over the first metal-containing gate electrode layer. The second MOS device includes a second gate dielectric on the semiconductor substrate; a second metal-containing gate electrode layer over the second gate dielectric; and a contact etch stop layer having a portion over the second metal-containing gate electrode layer, wherein a region between the portion of the contact etch stop layer and the second metal-containing gate electrode layer is substantially free from silicon.

Abstract: In one aspect, the present invention provides electronic devices that comprise a doped semiconductor shared contact between (a) a gate conductor region of at least one transistor and (b) a source/drain diffusion region of at least one transistor. One specific example of such as shared contact, among many others, is a doped SiGe shared contact between (a) a gate conductor region shared by an N-channel MOSFET and a P-channel MOSFET and (b) a drain diffusion region of an N-channel MOSFET or of a P-channel MOSFET.

Abstract: An electronic circuit includes a noise source and an analog circuit and a logic circuit that may be adversely affected by noise. At least a portion of the analog circuit and the logic circuit is formed on a buried impurity layer whose conductivity is different from that of a substrate, and at least a portion of the periphery of that portion is surrounded by an impurity layer that is different from the substrate. Thus, propagation of the noise from the noise source is prevented.

Abstract: A method of manufacturing a memory device includes an nMOS region and a pMOS region in a substrate. A first gate is defined within the nMOS region, and a second gate is defined in the pMOS region. Disposable spacers are simultaneously defined about the first and second gates. The nMOS and pMOS regions are selectively masked, one at a time, and LDD and Halo implants performed using the same masks as the source/drain implants for each region, by etching back spacers between source/drain implant and LDD/Halo implants. All transistor doping steps, including enhancement, gate and well doping, can be performed using a single mask for each of the NMOS and pMOS regions. Channel length can also be tailored by trimming spacers in one of the regions prior to source/drain doping.

Abstract: A device includes a semiconductor region in a semiconductor chip, a gate dielectric layer over the semiconductor region, and a gate electrode over the gate dielectric. A drain region is disposed at a top surface of the semiconductor region and adjacent to the gate electrode. A gate spacer is on a sidewall of the gate electrode. A dielectric layer is disposed over the gate electrode and the gate spacer. A conductive field plate is over the dielectric layer, wherein the conductive field plate has a portion on a drain side of the gate electrode. A deep metal via is disposed in the semiconductor region. A source electrode is underlying the semiconductor region, wherein the source electrode is electrically shorted to the conductive field plate through the deep metal via.

Abstract: Techniques are described to form a low-noise, high-gain semiconductor device. In one or more implementations, the device includes a substrate including a first dopant material having a concentration ranging from about 1×1010/cm3 to about 1×1019/cm3. The substrate also includes at least two active regions formed proximate to a surface of the substrate. The at least two active regions include a second dopant material, which is different than the first dopant material. The device further includes a gate structure formed over the surface of the substrate between the active regions. The gate structure includes a doped polycrystalline layer and an oxide layer formed over the surface between the surface and the doped polycrystalline layer. The doped polycrystalline layer includes the first dopant material having a concentration ranging from about 1×1019/cm3 to about 1×1021/cm3.

Abstract: A method for manufacturing a semiconductor power device on a semiconductor substrate supporting a drift region composed of an epitaxial layer by growing a first epitaxial layer followed by forming a first hard mask layer on top of the epitaxial layer; applying a first implant mask to open a plurality of implant windows and applying a second implant mask for blocking some of the implant windows to implant a plurality of dopant regions of alternating conductivity types adjacent to each other in the first epitaxial layer; repeating the first step and the second step by applying the same first and second implant masks to form a plurality of epitaxial layers then carrying out a device manufacturing process on a top side of the epitaxial layer with a diffusion process to merge the dopant regions of the alternating conductivity types as doped columns in the epitaxial layers.

Abstract: A device includes a semiconductor substrate, source and drain regions in the semiconductor substrate and having a first conductivity type, a gate structure supported by the semiconductor substrate between the source and drain regions, a well region in the semiconductor substrate, having a second conductivity type, and in which a channel region is formed under the gate structure during operation, and a shunt region adjacent the well region in the semiconductor substrate and having the second conductivity type. The shunt region has a higher dopant concentration than the well region to establish a shunt path for charge carriers of the second conductivity type that electrically couples the well region to a potential of the source region.

Abstract: An integrated circuit containing an analog MOS transistor has an implant mask for a well which blocks well dopants from two diluted regions at edges of the gate, but exposes a channel region to the well dopants. A thermal drive step diffuses the implanted well dopants across the two diluted regions to form a continuous well with lower doping densities in the two diluted regions. Source/drain regions are formed adjacent to and underlapping the gate by implanting source/drain dopants into the substrate adjacent to the gate using the gate as a blocking layer and subsequently annealing the substrate so that the implanted source/drain dopants provide a desired extent of underlap of the source/drain regions under the gate. Drain extension dopants and halo dopants are not implanted into the substrate adjacent to the gate.

Abstract: The invention relates to the field of fabricating a semiconductor integrated circuit and particularly to an integrated device and a method for fabricating the integrated device in order to address the problem that a drift area is fabricated on an epitaxial layer but the application scope of the LDMOS is limited due to the costly process of fabricating the epitaxial layer. An integrated device of an nLDMOS and a pLDMOS according to an embodiment of the invention includes a substrate and further includes an nLDMOS and a pLDMOS, where the nLDMOS and the pLDMOS are located in the substrate. The nLDMOS and the pLDMOS is located in the substrate without any epitaxial layer, thereby lowering the fabrication cost and extending the application scope.

Abstract: A semiconductor device and method of forming the same including, in one embodiment, a substrate and a plurality of source and drain regions formed as alternating pattern on the substrate. The semiconductor device also includes a plurality of gates formed over the substrate between and parallel to ones of the plurality of source and drain regions. The semiconductor device also includes a first plurality of alternating source and drain metallic strips formed in a first metallic layer above the substrate and parallel to and forming an electrical contact with respective ones of the plurality of source and drain regions.

Abstract: A method for fabricating a high voltage semiconductor device is provided. Firstly, a substrate is provided, wherein the substrate has a first active zone and a second active zone. Then, a first ion implantation process is performed to dope the substrate by a first mask layer, thereby forming a first-polarity doped region at the two ends of the first active zone and a periphery of the second active zone. After the first mask layer is removed, a second ion implantation process is performed to dope the substrate by a second mask layer, thereby forming a second-polarity doped region at the two ends of the second active zone and a periphery of the first active zone. After the second mask layer is removed, a first gate conductor structure and a second gate conductor structure are formed over the middle segments of the first active zone and the second active zone, respectively.

Abstract: 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 laterally diffused metal oxide semiconductor device includes a source/drain having a lightly doped region located adjacent the channel region and a heavily doped region located adjacent the lightly doped region. The laterally diffused metal oxide semiconductor device further includes an oppositely doped well located under and within the channel region, and a doped region, located between the heavily doped region and the oppositely doped well, having a doping concentration profile less than a doping concentration profile of the heavily doped region.

Abstract: A polarity switching member of a dot inversion system is revealed. A first transistor and a second transistor are disposed in a P-well while a N-well is arranged in the P-well, located between the first transistor and the second transistor. The N-well includes a third transistor and a fourth transistor. One end of the third transistor is coupled to one end of the first transistor to generate a first input end and one end of the fourth transistor is coupled to one end of the second transistor to generate a second input end. The other end of the first transistor, the other end of the second transistor, the other end of the third transistor, and the other end of the fourth transistor are coupled to generate an output end. Thereby, by switching of voltage polarity of the P-well and the N-well, a larger range of output voltage difference is achieved.

Abstract: A method for fabricating a semiconductor device is disclosed. A dummy gate feature is formed between two active gate features in an inter-layer dielectric (ILD) over a substrate. An isolation structure is in the substrate and the dummy gate feature is over the isolation structure. Source/drain (S/D) features are formed at edges of the active gate features in the substrate for forming transistor devices. The disclosed method provides an improved method for reducing parasitic capacitance among the transistor devices. In an embodiment, the improved formation method is achieved by introducing species into the dummy gate feature to increase the resistance of the dummy gate feature.

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: A power semiconductor device includes: a drain region of a first conductive type; a drift region of a first conductive type formed on the drain region; a first body region of a second conductive type formed below an upper surface of the drift region; a second body region of a second conductive type formed below the upper surface of the drift region and in the first body region; a third body region of a second conductive type formed by protruding downwards from a lower end of the first body region; a source region of a first conductive type formed below the upper surface of the drift region and in the first body region; and a gate insulating layer formed on channel regions of the first body region and on the drift region between the first body regions.

Abstract: There is provided an MOSFET having a large current density, which can be mixed with a logic circuit, and is used in a circuit that conducts the operation of applying a negative voltage to a drain electrode. An electrode surrounded by an insulating film is formed, at an intermediate position of a gate electrode and a drain of the MOSFET formed on an SOI substrate having a drain electrode applied with a negative voltage, and the electrode is connected to the ground to prevent a withstand voltage from being lowered which is caused by an increase in impurity concentration of a drift region. A drift resistance is lowered to improve the current density.

Abstract: A semiconductor device includes a high breakdown voltage DMOS transistor formed on a first conductivity type semiconductor substrate. The semiconductor device includes: a DMOS second conductivity type well; a DMOS first conductivity body region; a DMOS second conductivity type source region; a DMOS second conductivity type drain region; a LOCOS oxide film formed between the DMOS second conductivity type drain region and the DMOS first conductivity type body region; and a DMOS gate insulating film formed in succession to the LOCOS oxide film to cover a DMOS channel region between the DMOS second conductivity type source region and the DMOS second conductivity type well, wherein the DMOS gate insulating film includes a first insulating film which is disposed outside the DMOS channel region and a second insulating film which is disposed in the DMOS channel region and is thinner than the first insulating film.

Abstract: A solid-state image sensor including a plurality of pixels formed on a semiconductor substrate, each pixel comprising a photoelectric conversion element including a charge accumulation region of a first conductivity type, a floating diffusion of the first conductivity type, and a transfer transistor which transfers charge in the charge accumulation region to the floating diffusion, comprises an element isolation region made of an insulator and arranged to isolate adjacent pixels from each other, and an impurity diffusion region of a second conductivity type arranged inside the semiconductor substrate to isolate adjacent pixels from each other, wherein a peak position of an impurity concentration of the impurity diffusion region of one pixel is disposed within a width of the floating diffusion, of the one pixel, along a straight line passing through the photoelectric conversion element, a gate electrode of the transfer transistor, and the floating diffusion which are of the one pixel.

Abstract: A semiconductor device and a fabrication method thereof are provided. The semiconductor device includes a P type well region and an N type well region formed in a substrate, a gate insulating layer having a non-uniform thickness and formed on the P type well region and the N type well region, a gate electrode formed on the gate insulating layer, a P type well pick-up region formed in the P type well region, and a field relief oxide layer formed in the N type well region between the gate electrode and the drain region.