Abstract: A high voltage semiconductor device includes a semiconductor substrate, a p type base region in a first main surface, an n+ type emitter region in the p type base region, an n+ type cathode region adjacent to an end surface of the semiconductor substrate and not penetrating the semiconductor substrate, a p+ type collector region in a second main surface, a first main electrode, a second main electrode, a third main electrode, and a connection portion connecting the second main electrode and the third main electrode. A resistance between the p type base region and the n+ type cathode region is greater than a resistance between the p type base region and the p+ type collector region. In the high voltage semiconductor device in which an IGBT and a free wheel diode are formed in a single semiconductor substrate, occurrence of a snap-back phenomenon is suppressed.

Abstract: Provided are a multiple-gate MOS (metal oxide semiconductor) transistor and a method of manufacturing the same. The transistor includes a single crystalline active region having a channel region having an upper portion of a streamlined shape (?) obtained by patterning an upper portion of a bulk silicon substrate with an embossed pattern, and having a thicker and wider area than the channel region; a nitride layer formed at both side surfaces of the single crystalline active region to expose an upper portion of the single crystalline active region at a predetermined height; and a gate electrode formed to be overlaid with the exposed upper portion of the single crystalline active region of the channel region.

Abstract: A LDD layer of the second conduction type locates in the surface of a semiconductor layer beneath a sidewall insulator film. A source layer of the second conduction type is formed in the surface of the semiconductor layer at a position adjacent to the LDD layer. A resurf layer of the second conduction type is formed in the surface of the semiconductor layer at a position sandwiching the gate electrode with the LDD layer. A drain layer of the second conduction type is formed in the surface of the semiconductor layer at a position adjacent to the resurf layer. The resurf layer is formed in depth to have peaks of a first and a second impurity concentration in turn from the surface of the semiconductor layer. The peak of the first impurity concentration is smaller than the peak of the second impurity concentration.

Abstract: Semiconductor structures and methods of forming semiconductor structures, and more particularly to structures and methods of forming SiGe and/or SiGeC buried layers for SOI/SiGe devices. An integrated structure includes discontinuous, buried layers having alternating Si and SiGe or SiGeC regions. The structure further includes isolation structures at an interface between the Si and SiGe or SiGeC regions to reduce defects between the alternating regions. Devices are associated with the Si and SiGe or SiGeC regions. The invention is also directed to a design structure on which a circuit resides.

Abstract: A high-voltage metal-oxide-semiconductor (HVMOS) device having increased breakdown voltage and methods for forming the same are provided. The HVMOS device includes a semiconductor substrate; a gate dielectric on a surface of the semiconductor substrate; a gate electrode on the gate dielectric; a source/drain region adjacent and horizontally spaced apart from the gate electrode; and a recess in the semiconductor substrate and filled with a dielectric material. The recess is between the gate electrode and the source/drain region, and is horizontally spaced apart from the gate electrode.

Abstract: A MOS device includes first and second source/drains spaced apart relative to one another. A channel is formed in the device between the first and second source/drains. A gate is formed in the device between the first and second source/drains and proximate the channel, the gate being electrically isolated from the first and second source/drains and the channel. The gate is configured to control a conduction of the channel as a function of a potential applied to the gate. The MOS device further includes an energy filter formed between the first source/drain and the channel. The energy filter includes a superlattice structure wherein a mini-band is formed. The energy filter is operative to control an injection of carriers from the first source/drain into the channel. The energy filter, in combination with the first source/drain, is configured to produce an effective zero-Kelvin first source/drain.

Abstract: A semiconductor device for reducing junction capacitance by an additional low dose super deep source/drain implant and a method for its fabrication are disclosed. In particular, the super deep implant is performed after spacer formation to significantly reduce junction capacitance in the channel region.

Abstract: In a semiconductor device, typically an active matrix display device, the structure of TFTs arranged in the respective circuits are made suitable in accordance with the function of the circuit, and along with improving the operating characteristics and the reliability of the semiconductor device, the manufacturing cost is reduced and the yield is increased by reducing the number of process steps.

Abstract: The semiconductor device of the present invention includes: a gate insulating film formed on a semiconductor region of a first conductivity type; a gate electrode formed on the gate insulating film; and a channel doped layer of the first conductivity type formed in the semiconductor region beneath the gate electrode. The channel doped layer contains carbon as an impurity.

Abstract: An electro-optical substrate, including: a transparent substrate; a first light-shielding layer arranged on a first surface of the transparent substrate, in at least part of a region surrounding an opening in plan view; a first insulating layer arranged in a position facing the transparent substrate with the first light-shielding layer interposed therebetween, the first insulating layer having a refraction index n and a layer thickness t measured in nanometers, and covering at least part of the first light-shielding layer; a semiconductor layer, arranged in a position facing the transparent substrate, with the first light-shielding layer interposed therebetween, containing part of a thin film transistor, the thin film transistor including a channel region which is, in plan view, positioned within the first light-shielding layer, a corner edge of the first light-shielding layer and a corner edge of the channel region having a distance Lc therebetween in nanometers, the distance Lc satisfying relational express

Abstract: A MOSFET includes a gate having a high-k gate dielectric on a substrate and a gate electrode on the gate dielectric. The gate dielectric protrudes beyond the gate electrode. A deep source and drain having shallow extensions are formed on either side of the gate. The deep source and drain are formed by selective in-situ doped epitaxy or by ion implantation and the extensions are formed by selective, in-situ doped epitaxy. The extensions lie beneath the gate in contact with the gate dielectric. The material of the gate dielectric and the amount of its protrusion beyond the gate electrode are selected so that epitaxial procedures and related procedures do not cause bridging between the gate electrode and the source/drain extensions. Methods of fabricating the MOSFET are described.

Abstract: There is provided a semiconductor device including a semiconductor substrate (10), a high concentration diffusion region (22) formed within the semiconductor substrate (10), a first low concentration diffusion region (24) that has a lower impurity concentration than the high concentration diffusion region (22) and is provided under the high concentration diffusion region (22), and a bit line(30) that includes the high concentration diffusion region (22) and the first low concentration diffusion region (24) and serves as a source region and a drain region, and a manufacturing method therefor. Reduction of source-drain breakdown voltage of the transistor is suppressed, and a low-resistance bit line can be formed. Thus, a semiconductor device that can miniaturize memory cells and a manufacturing method therefor can be provided.

Abstract: A high voltage/power semiconductor device using a low voltage logic well is provided. The semiconductor device includes a substrate, a first well region formed by being doped in a first location on a surface of the substrate, a second well region formed by being doped with impurity different from the first well region's in a second location on a surface of the substrate, an overlapping region between the first well region and the second well region where the first well region and the second well region substantially coexist, a gate insulating layer formed on the surface of the first and the second well regions and the surface of the overlapping region, a gate electrode formed on the gate insulating layer, a source region formed on an upper portion of the first well region, and a drain region formed on an upper portion of the second well region.

Abstract: A peripheral circuit includes at least a first transistor. The first transistor comprises a gate electrode formed on a surface of a semiconductor layer via a gate insulating film. A channel region of a first conductivity type having a first impurity concentration is formed on a surface of the semiconductor layer directly below and in the vicinity of the gate electrode. A source-drain diffusion region of the first conductivity type is formed on the surface of the semiconductor layer to sandwich the gate electrode and has a second impurity concentration greater than the first impurity concentration. An overlapping region of the first conductivity type is formed on the surface of the semiconductor layer directly below the gate electrode where the channel region and the source-drain diffusion region overlap. The overlapping region has a third impurity concentration greater than the second impurity concentration.

Abstract: According to one embodiment, a method for selective gate halo implantation includes forming at least one gate having a first orientation and at least one gate having a second orientation over a substrate. The method further includes performing a halo implant over the substrate. The first orientation allows a halo implanted area to be formed under the at least one gate having the first orientation and the second orientation prevents a halo implanted area from forming under the at least one gate having the second orientation. The halo implant is performed without forming a mask over the at least one gate having the first orientation or the at least one gate having the second orientation. The at least one gate having the first orientation can be used in a low voltage region of a substrate, while the at least one gate having the second orientation can be used in a high voltage region.

Abstract: A semiconductor structure comprises a gate stack in a semiconductor substrate and a lightly doped source/drain (LDD) region in the semiconductor substrate. The LDD region is adjacent to a region underlying the gate stack. The LDD region comprises carbon and an n-type impurity, and the n-type impurity comprises phosphorus tetramer.

Abstract: In one exemplary embodiment, a method for fabricating a nanowire product comprising: providing a wafer having a buried oxide (BOX) upper layer in which a well is formed, the wafer further having a nanowire having ends resting on the BOX layer such that the nanowire forms a beam spanning said well; and forming a mask coating on an upper surface of the BOX layer leaving an uncoated window over a center part of said beam over said well and also forming a mask coating around beam intermediate ends between each end of a beam center part and a side wall of said well.

Abstract: A semiconductor structure includes a semiconductor substrate comprising a PMOS region and an NMOS region; a PMOS device in the PMOS region; and an NMOS device in the NMOS region. The PMOS device includes a first gate stack on the semiconductor substrate; a first offset spacer on a sidewall of the first gate stack; a stressor in the semiconductor substrate and adjacent to the first offset spacer; and a first raised source/drain extension region on the stressor and adjoining the first offset spacer, wherein the first raised source/drain extension region has a higher p-type dopant concentration than the stressor.

Abstract: A memory cell includes a FinFET select device and a memory element. In some embodiments a memory cell has a contact element coupled between a surface of the fin and the memory element.

Abstract: Provided is a LDMOS device and method for manufacturing. The LDMOS device includes a second conductive type buried layer formed in a first conductive type substrate. A first conductive type first well is formed in the buried layer and a field insulator with a gate insulating layer at both sides are formed on the first well. On one side of the field insulator is formed a first conductive type second well and a source region formed therein. On the other side of the field insulator is formed an isolated drain region. A gate electrode is formed on the gate insulating layer on the source region and a first field plate is formed on a portion of the field insulator and connected with the gate electrode. A second field plate is formed on another portion of the field insulator and spaced apart from the first field plate.

Abstract: A semiconductor device includes: a first semiconductor region formed on a substrate and having an upper surface and a side surface; a first impurity region of a first conductivity type formed in an upper portion of the first semiconductor region; a second impurity region of a first conductivity type formed in a side portion of the first semiconductor region; and a gate insulating film formed so as to cover at least a side surface and an upper corner of a predetermined portion of the first semiconductor region. A radius of curvature r? of an upper corner of a portion of the first semiconductor region located outside the gate insulating film is greater than a radius of curvature r of an upper corner of a portion of the first semiconductor region located under the gate insulating film and is less than or equal to 2r.

Abstract: A semiconductor device for ESD protection includes a semiconductor substrate of a first conductivity type and a well region of a second conductivity type formed within the substrate. The well region is characterized by a first depth. The device includes an MOS transistor, a first bipolar transistor, and a second bipolar transistor. The MOS transistor includes a first lightly doped drain (LDD) region of a second depth within the well region, and a drain region and an emitter region within in the first LDD region. The emitter region is characterized by a second conductivity type. The first bipolar transistor is associated with the emitter region, the first LDD region, and the well region, and is characterized by a first trigger voltage. The second bipolar transistor is associated with the first LDD region, the well region, and the substrate, and is characterized by a second trigger voltage.

Abstract: Disclosed are a semiconductor device and a method of fabricating the same. The semiconductor device can include a transistor structure including a gate electrode and a first channel region and source/drain regions on a substrate, and a second channel region and source/drain regions provided on the transistor structure. Accordingly, transistor operations can utilize the current path above and below the gate electrode.

Abstract: A technique for and structures for camouflaging an integrated circuit structure. The technique including forming active areas of a first conductivity type and LDD regions of a second conductivity type resulting in a transistor that is always non-operational when standard voltages are applied to the device.

Abstract: There is provided a thin film transistor having improved reliability. A gate electrode includes a first gate electrode having a taper portion and a second gate electrode with a width narrower than the first gate electrode. A semiconductor layer is doped with phosphorus of a low concentration through the first gate electrode. In the semiconductor layer, two kinds of n?-type impurity regions are formed between a channel formation region and n+-type impurity regions. Some of the n?-type impurity regions overlap with a gate electrode, and the other n?-type impurity regions do not overlap with the gate electrode. Since the two kinds of n?-type impurity regions are formed, an off current can be reduced, and deterioration of characteristics can be suppressed.

Abstract: Methods of manufacturing a semiconductor device include forming a gate electrode on a semiconductor substrate, forming spacers on side walls of the gate electrode, and doping impurities into the semiconductor substrate on both sides of the spacers to form highly doped impurity regions. The spacers are selectively etched to expose portions of the semiconductor substrate, and more lightly doped impurity regions are formed in the semiconductor substrate between the highly doped impurity regions and the gate electrode.

Abstract: A semiconductor integrated circuit comprising thin-film transistors in each of which the second wiring is prevented from breaking at steps. A silicon nitride film is formed on gate electrodes and on gate wiring extending from the gate electrodes. Substantially triangular regions are formed out of an insulator over side surfaces of the gate electrodes and of the gate wiring. The presence of these substantially triangular side walls make milder the steps at which the second wiring goes over the gate wiring. This suppresses breakage of the second wiring.

Abstract: The present invention provides a semiconductor device in which a bottom-gate TFT or an inverted stagger TFT arranged in each circuit is suitably constructed in conformity with the functionality of the respective circuits, thereby attaining an improvement in the operating efficiency and reliability of the semiconductor device. In the structure, LDD regions in a pixel TFT are arranged so as not to overlap with a channel protection insulating film and to overlap with a gate electrode by at least a portion thereof. LDD regions in an N-channel TFT of a drive circuit is arranged so as not to overlap with a channel protection insulating film and to overlap with a gate electrode by at least a portion thereof. LDD regions in a P-channel TFT of the drive circuit is arranged so as to overlap with a channel protection insulating film and to overlap with the gate electrode.

Abstract: A memory cell includes a FinFET select device and a memory element. In some embodiments a memory cell has a contact element coupled between a surface of the fin and the memory element.

Abstract: A method for manufacturing a semiconductor device includes forming a first gate electrode on a semiconductor substrate in a first transistor region; forming a channel dose region; and forming a first source extension region, wherein the channel dose region is formed by using a first mask as a mask and by ion-implanting a first dopant of the first conductivity type, and the first mask covering a drain side of the first gate electrode and covering a drain region, and the first source extension region is formed by using a second mask and the gate electrode as masks and by ion-implanting a second dopant of a second conductivity type that is a conductivity type opposite to the first conductivity type, the second mask covering the drain side of the first gate electrode and covering the drain region.

Abstract: An insulated-gate field-effect transistor (100, 100V, 140, 150, 150V, 160, 170, 170V, 180, 180V, 190, 210, 210W, 220, 220U, 220V, 220W, 380, or 480) has a hypoabrupt vertical dopant profile below one (104 or 264) of its source/drain zones for reducing the parasitic capacitance along the pn junction between that source/drain zone and adjoining body material (108 or 268). In particular, the concentration of semiconductor dopant which defines the conductivity type of the body material increases by at least a factor of 10 in moving from that source/drain zone down to an underlying body-material location no more than 10 times deeper below the upper semiconductor surface than that source/drain zone. The body material preferably includes a more heavily doped pocket portion (120 or 280) situated along the other source/drain zone (102 or 262).

Abstract: A method of forming ultra-shallow p-type lightly doped drain (LDD) regions of a PMOS transistor in a surface of a substrate includes the steps of providing a gaseous mixture of an inert gas, a boron-containing source, and an optional carbon-containing source, wherein the concentration of the gaseous mixture is at least 99.5% dilute with the inert gas and the optional carbon-containing source, if present, forming the gaseous mixture into a plasma, and forming the LDD regions, wherein the forming step includes plasma-doping the boron into the substrate using the plasma. N-type pocket regions are formed in the substrate underneath and adjacent to the LDD regions, wherein for a PMOS transistor having a threshold voltage of 100 mV, the n-type pocket regions include phosphorous impurities at a dopant concentration of less than 6.0×1018 atoms/cm3 or a proportionately lower/higher dopant concentration for a lower/higher threshold voltage.

Abstract: A semiconductor device includes first and second MOSFETs corresponding to at least first power source voltage and second power source voltage lower than the first power source voltage, and non-silicide regions formed in drain portions of the first and second MOSFETs and having no silicide formed therein. The first MOSFET includes first diffusion layers formed in source/drain portions, a second diffusion layer formed below a gate portion and formed shallower than the first diffusion layer and a third diffusion layer formed with the same depth as the second diffusion layer in the non-silicide region, and the second MOSFET includes fourth diffusion layers formed in source/drain portions, a fifth diffusion layer formed below a gate portion and formed shallower than the fourth diffusion layer and a sixth diffusion layer formed shallower than the fourth diffusion layer and deeper than the fifth diffusion layer in the non-silicide region.

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 device according to the present invention includes a semiconductor substrate of a first conductivity type having a top surface and a rear surface, a semiconductor layer of a second conductivity type formed on the top surface of the semiconductor substrate, having a top surface and a rear surface, and having the rear surface in contact with the top surface of the semiconductor substrate, a body region of the first conductivity type formed in a top layer portion of the semiconductor layer, a first impurity region of the second conductivity type formed in a top layer portion of the semiconductor layer and spaced apart from the body region, a second impurity region of the second conductivity type formed in a top layer portion of the body region and spaced apart from a peripheral edge of the body region, a gate electrode formed on the semiconductor layer and opposed to a portion between the peripheral edge of the body region and a peripheral edge of the second impurity region, a field insulating fi

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: An asymmetric insulated-gate field-effect transistor (100) has a source (240) and a drain (242) laterally separated by a channel zone (244) of body material (180) of a semiconductor body. A gate electrode (262) overlies a gate dielectric layer (260) above the channel zone. A more heavily doped pocket portion (250) of the body material extends largely along only the source. Each of the source and drain has a main portion (240M or 242M) and a more lightly doped lateral extension (240E or 242E). The drain extension is more lightly doped than the source extension. The maximum concentration of the semiconductor dopant defining the two extensions occurs deeper in the drain extension than in the source extension. Additionally or alternatively, the drain extension extends further laterally below the gate electrode than the source extension. These features enable the threshold voltage to be highly stable with operational time.

Abstract: A semiconductor structure includes a symmetric metal-oxide-semiconductor (MOS) transistor comprising a first and a second asymmetric MOS transistor. The first asymmetric MOS transistor includes a first gate electrode, and a first source and a first drain adjacent the first gate electrode. The second asymmetric MOS transistor includes a second gate electrode, and a second source and a second drain adjacent the second gate electrode. The first gate electrode is connected to the second gate electrode, wherein only one of the first source and the first drain is connected to only one of the respective second source and the second drain.

Abstract: A semiconductor device including a low-concentration impurity region formed on the drain side of an n-type MIS transistor, in a non-self-aligned manner with respect to an end portion of the gate electrode. A high-concentration impurity region is placed with a specific offset from the gate electrode and a sidewall insulating film. The semiconductor device enables the drain breakdown voltage to be sufficient and the on-resistance to decrease. A silicide layer is also formed on the surface of the gate electrode, thereby achieving gate resistance reduction and high frequency characteristics improvement.

Abstract: In a method for manufacturing a semiconductor device having an N-channel field effect transistor, the N-channel field effect transistor is formed by a process including the steps of forming a high dielectric constant gate insulating film on a substrate, forming a gate electrode on the high dielectric constant gate insulating film, forming an extension region by introducing N-type impurities into the substrate by using at least the gate electrode as a mask, and forming a pocket region by introducing P-type impurities under the extension region in the substrate by using at least the gate electrode as a mask. An amount of arsenic (As) that is introduced as the N-type impurities is in a range that is equal to or lower than a prescribed value that is determined based on a thickness of the high dielectric constant gate insulating film.

Abstract: Thin film transistors (TFT) and methods for making same. The TFTs generally comprise: (a) a semiconductor layer comprising source and drain terminals and a channel region therebetween; (b) a gate electrode comprising a gate and a gate dielectric layer between the gate and the channel region; (c) a first dielectric layer adjacent to the gate electrode and in contact with the source and drain terminals, the first dielectric layer comprising a material which comprises a dopant therein; and (d) an electrically functional source/drain extensions in the channel region, adjacent to the source and drain terminals, comprising a material which comprises the same dopant as the first dielectric layer.

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 method for manufacturing a semiconductor resistor includes forming a well region in a semiconductor substrate, with the well region serving as a resistive region, forming a pair of contact regions spaced apart from each other in the well region, and forming a diffusion region in an intermediate portion between the pair of contact regions on a surface of the well region. The diffusion region is configured to adjust resistance and temperature dependence of the semiconductor resistor.

Abstract: A semiconductor device manufacturing method and a semiconductor device manufacturing system for irradiating a first laser light (50) and a second laser light (52) with a wavelength different from that of the first laser light to a substrate (46) to perform a thermal processing on the substrate are provided. In the step for performing the thermal processing, at least one of an irradiation intensity and an irradiation time of a first laser and a second laser is controlled to control a temperature distribution in the substrate or a film on the substrate in a depth direction.

Abstract: A semiconductor device includes: a p-type active region; a gate electrode traversing the active region; an n-type LDD region having a first impurity concentration and formed from a drain side region to a region under the gate electrode; a p-type channel region having a second impurity concentration and formed from a source side region to a region under the gate electrode to form an overlap region with the LDD region under the gate electrode, the channel region being shallower than the LDD region; an n-type source region formed outside the gate electrode; and an n+-type drain region having a third impurity concentration higher than the first impurity concentration formed outside and spaced from the gate electrode, wherein an n-type effective impurity concentration of an intermediate region between the gate electrode and the n+-type drain region is higher than an n-type effective impurity concentration of the overlap region.

Abstract: There is provided a semiconductor device having a metal silicide layer which can suppress the malfunction and the increase in power consumption of the device. The semiconductor device has a semiconductor substrate containing silicon and having a main surface, first and second impurity diffusion layers formed in the main surface of the semiconductor substrate, a metal silicide formed over the second impurity diffusion layer, and a silicon nitride film and a first interlayer insulation film sequentially stacked over the metal silicide. In the semiconductor device, a contact hole penetrating through the silicon nitride film and the first interlayer insulation film, and reaching the surface of the metal silicide is formed. The thickness of a portion of the metal silicide situated immediately under the contact hole is smaller than the thickness of a portion of the metal silicide situated around the contact hole.

Abstract: A method of making a FET includes forming a gate structure (18), then etching cavities on either side. A SiGe layer (22) is then deposited on the substrate (10) in the cavities, followed by an Si layer (24). A selective etch is then carried out to etch away the SiGe (22) except for a part of the layer under the gate structure (18), and oxide (28) is grown to fill the resulting gap. SiGe source and drains are then deposited in the cavities. The oxide (28) can reduce junction leakage current.

Abstract: Methods and devices for forming both high-voltage and low-voltage transistors on a common substrate using a reduced number of processing steps are disclosed. An exemplary method includes forming at least a first high-voltage transistor well and a first low-voltage transistor well on a common substrate separated by an isolation structure extending a first depth into the substrate, using a first mask and first implantation process to simultaneously implant a doping material of a first conductivity type into a channel region of the low-voltage transistor well and a drain region for the high-voltage transistor well.

Abstract: A high voltage device includes a substrate with a device region defined thereon. A gate stack is disposed on the substrate in the device region. A channel region is located in the substrate beneath the gate stack, while a first diffusion region is located in the substrate on a first side of the gate stack. A first isolation structure in the substrate, located on the first side of the gate stack, separates the channel and the first diffusion region. The high voltage device also includes a first drift region in the substrate coupling the channel to the first diffusion region, wherein the first drift region comprises a non-uniform depth profile conforming to a profile of the first isolation structure.

Abstract: Reduced source resistance is realized in a laterally diffused MOS transistor by fabricating the transistor in a P-doped epitaxial layer on an N-doped semiconductor substrate and using a trench contact for ohmically connecting the N-doped source region to the N-doped substrate.