Abstract: A semiconductor device is provided. The semiconductor device includes a plurality of first epitaxial layers, a second epitaxial layer and a gate structure. The plurality of first epitaxial layers is stacked on a substrate and has a first conductivity type. Each first epitaxial layer includes at least one first doping region and at least one second doping region adjacent thereto. The first doping region has a second conductivity and the second doping region has the first conductivity type. The second epitaxial layer is disposed on the plurality of first epitaxial layers, having the first conductivity type. The second epitaxial layer has a trench therein and a third doping region having the second conductivity type is adjacent to a sidewall of the trench. The gate structure is disposed on the second epitaxial layer above the second doping region. A method of fabricating a semiconductor device is also disclosed.

Abstract: A staggered column superjunction semiconductor device may include a cell region having one or more device cells. One or more device cells in the cell region include a semiconductor substrate configured to act as a drain and a semiconductor layer formed on the substrate. A first doped column may be formed in the semiconductor layer to a first depth and a second doped column may be formed in the semiconductor layer to a second depth. The first depth is greater than the second depth. The first and second columns are doped with dopants of a same second conductivity type and extend along a portion of a thickness of the semiconductor layer and are separated from each by a portion of the semiconductor layer.

Abstract: A semiconductor component with a drift region and a drift control region. One embodiment includes a semiconductor body having a drift region of a first conduction type in the semiconductor body. A drift control region composed of a semiconductor material, which is arranged, at least in sections, is adjacent to the drift region in the semiconductor body. An accumulation dielectric is arranged between the drift region and the drift control region.

Abstract: An embodiment of a process for manufacturing a power semiconductor device envisages the steps of: providing a body of semiconductor material having a top surface and having a first conductivity; forming columnar regions having a second type of conductivity within the body of semiconductor material, and surface extensions of the columnar regions above the top surface; and forming doped regions having the second type of conductivity, in the proximity of the top surface and in contact with the columnar regions. The doped regions are formed at least partially within the surface extensions of the columnar regions; the surface extensions and the doped regions have a non-planar surface pattern, in particular with a substantially V-shaped groove.

Abstract: A method to form a LDMOS transistor includes forming a gate/source/body opening and a drain opening in a field oxide on a substrate structure, forming a gate oxide in the gate/source/body opening, and forming a polysilicon layer over the substrate structure. The polysilicon layer is anisotropically etched to form polysilicon spacer gates separated by a space in the gate/source/body opening and a polysilicon drain contact in the drain opening. A body region is formed self-aligned about outer edges of the polysilicon spacer gates, a source region is formed self-aligned about inner edges of the polysilicon spacer gates, and a drain region is formed under the polysilicon drain contact and self-aligned with respect to the polysilicon spacer gates. A drift region forms in the substrate structure between the body region and the drain region, and a channel region forms in the body region between the source region and the drift region.

Abstract: A semiconductor device includes a drift zone of a first conductivity type formed within a semiconductor body, wherein one side of opposing sides of the drift zone adjoins a first zone within the semiconductor body and the other side adjoins a second zone within the semiconductor body. First semiconductor subzones of a second conductivity type different from the first conductivity type are formed within each of the first and second zones opposing each other along a lateral direction extending parallel to a surface of the semiconductor body. A second semiconductor subzone is formed within each of the first and second zones and between the first semiconductor subzones along the lateral direction. An average concentration of dopants within the second semiconductor subzone along 10% to 90% of an extension of the second semiconductor subzone along a vertical direction perpendicular to the surface is smaller than the average concentration of dopants along a corresponding section of extension within the drift zone.

Abstract: A power layout of an integrated circuit includes at least one power grid cell. Each power gird cell includes at least one first power layer configured to be coupled to a high power supply voltage and at least one second power layer configured to be coupled to a lower power supply voltage. The at least one first power layer has conductive lines in at least two different directions. The at least one second power layer has conductive lines in at least two different directions.

Abstract: Described is a method for fabricating a semiconductor device having an FET of a trench-gate structure obtained by disposing a conductive layer, which will be a gate, in a trench extended in the main surface of a semiconductor substrate, wherein the upper surface of the trench-gate conductive layer is formed equal to or higher than the main surface of the semiconductor substrate. In addition, the conductive layer of the trench gate is formed to have a substantially flat or concave upper surface and the upper surface is formed equal to or higher than the main surface of the semiconductor substrate. Moreover, after etching of the semiconductor substrate to form the upper surface of the conductive layer of the trench gate equal to or higher than the main surface of the semiconductor substrate, a channel region and a source region are formed by ion implantation. The semiconductor device thus fabricated according to the present invention is free from occurrence of a source offset.

Abstract: In one embodiment, the invention comprises a MOSFET comprising individual MOSFET cells. Each cell comprises a U-shaped well (228) (P type) and two parallel sources (260) (N type) formed within the well. A plurality of source rungs (262) (doped N) connect sources (260) at multiple locations. Regions between two rungs (262) comprise a body (252) (P type). These features are formed on an N-type epitaxial layer (220), which is formed on an N-type substrate (216). A contact (290) extends across and contacts a plurality of source rungs (262) and bodies (252). Gate oxide and a gate contact overlie a leg of a first well and a leg of a second adjacent well, inverting the conductivity responsive to a gate voltage. A MOSFET comprises a plurality of these cells to attain a desired low channel resistance. The cell regions are formed using self-alignment techniques at several states of the fabrication process.

Abstract: In one embodiment, the invention comprises a MOSFET comprising individual MOSFET cells. Each cell comprises a U-shaped well (228) (P type) and two parallel sources (260) (N type) formed within the well. A plurality of source rungs (262) (doped N) connect sources (260) at multiple locations. Regions between two rungs (262) comprise a body (252) (P type). These features are formed on an N-type epitaxial layer (220), which is formed on an N-type substrate (216). A contact (290) extends across and contacts a plurality of source rungs (262) and bodies (252). Gate oxide and a gate contact overlie a leg of a first well and a leg of a second adjacent well, inverting the conductivity responsive to a gate voltage. A MOSFET comprises a plurality of these cells to attain a desired low channel resistance. The cell regions are formed using self-alignment techniques at several states of the fabrication process.

Abstract: According to one embodiment, a semiconductor device includes a first and a second semiconductor layer of a first conductivity type, a third semiconductor layer of a second conductivity type, a source region of the first conductivity type, a first and a second main electrode, trench gates, a first and a second contact region. The third semiconductor layer is provided on the second semiconductor layer provided on the first semiconductor layer. The first main electrode is electrically connected to the first semiconductor layer. The second main electrode is electrically connected to the source region provided on the third semiconductor layer. The trench gates are provided from the third semiconductor layer to the second semiconductor layer. The first and second contact regions electrically connect the second main electrode and the third semiconductor layer. An opening area of the second contact hole is smaller than that of the first contact hole.

Abstract: A DMOS transistor is fabricated with its source/body/deep body regions formed on the walls of a first set of trenches, and its drain regions formed on the walls of a different set of trenches. A gate region that is formed in a yet another set of trenches can be biased to allow carriers to flow from the source to the drain. Lateral current low from source/body regions on trench walls increases the active channel perimeter to a value well above the amount that would be present if the device was fabricated on just the surface of the wafer. Masking is avoided while open trenches are present. A transistor with a very low on-resistance per unit area is obtained.

Abstract: A display device includes: a conductive layer on which gate electrodes are formed; a first insulation layer which is formed on the conductive layer; a semiconductor layer which is formed on the first insulation layer and is provided for forming semiconductor films which contain poly-crystalline silicon above the gate electrodes; and a second insulation layer which is formed on the semiconductor layer. Here, the semiconductor film includes a channel region which overlaps with the gate electrode as viewed in a plan view. In the channel region, a portion of the semiconductor film which is in contact with the second insulation layer exhibits higher impurity concentration than a portion of the semiconductor film which is in contact with the first insulation layer.

Abstract: A super junction transistor includes a drain substrate, an epitaxial layer, wherein the epitaxial layer is disposed on the drain substrate, a plurality of gate structure units embedded on the surface of the epitaxial layer, a plurality of trenches disposed in the epitaxial layer between the drain substrate and the gate structure units, a buffer layer in direct contact with the inner surface of the trenches, a plurality of body diffusion regions with a first conductivity type adjacent to the outer surface of the trenches, wherein there is at least a PN junction on the interface between the body diffusion region and the epitaxial layer, and a doped source region, wherein the doped source region is disposed in the epitaxial layer and is adjacent to the gate structure unit.

Abstract: A semiconductor device includes a semiconductor layer of a first conductivity type and a first doping concentration. A first semiconductor region, used as drain, of the first conductivity type has a lower doping concentration than the semiconductor layer and is over the semiconductor layer. A gate dielectric is over the first semiconductor region. A gate electrode over the gate dielectric has a metal-containing center portion and first and second silicon portions on opposite sides of the center portion. A second semiconductor region, used as a channel, of the second conductivity type has a first portion under the first silicon portion and the gate dielectric. A third semiconductor region, used as a source, of the first conductivity type is laterally adjacent to the first portion of the second semiconductor region. The metal-containing center portion, replacing silicon, increases the source to drain breakdown voltage.

Abstract: In one embodiment, an edge seal region of a semiconductor die is formed by forming a first dielectric layer on a surface of a semiconductor substrate near an edge of the semiconductor die and extending across into a scribe grid region of the semiconductor substrate. Another dielectric layer is formed overlying the first dielectric layer. An opening is formed through the first and second dielectric layers. The second dielectric layer is used as a mask for forming a doped region on the semiconductor substrate through the opening. A metal is formed that electrically contacts the doped region and an exterior edge of the first dielectric layer within the opening.

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

Abstract: Electrically isolated, deep trench isolation (DTI) structures, are formed in a wafer, and a portion of the DTI structures are converted to electrically connected structures to provide a shielding function, or to provide connection to deep buried layers. In one aspect, DTI structures include a polysilicon filling over a liner layer disposed on the inner surface of a deep trench, the polysilicon is removed by isotropic etching, and the deep trench is re-filled with a conductive material. Alternatively, the polysilicon filling remains and a contact is formed to provide an electrical connection to the polysilicon. In another aspect, a deep trench is disposed in the wafer such that a lower portion thereof is located within a deep buried layer, and after the polysilicon is removed, an anisotropic etch removes a portion of the deep trench liner from the bottom of the deep trench, thereby allowing a tungsten deposition to make electrical contact with the deep buried layer.

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

Abstract: A method of forming a semiconductor device may include forming a terminal region of a first conductivity type within a semiconductor layer of the first conductivity type. A well region of a second conductivity type may be formed within the semiconductor layer wherein the well region is adjacent at least portions of the terminal region within the semiconductor layer, a depth of the well region into the semiconductor layer may be greater than a depth of the terminal region into the semiconductor layer, and the first and second conductivity types may be different. An epitaxial semiconductor layer may be formed on the semiconductor layer, and a terminal contact region of the first conductivity type may be formed in the epitaxial semiconductor layer with the terminal contact region providing electrical contact with the terminal region. In addition, an ohmic contact may be formed on the terminal contact region. Related structures are also discussed.

Abstract: A semiconductor device is formed on a semiconductor substrate. The device includes a drain, an epitaxial layer overlaying the drain, and an active region. The active region includes a body disposed in the epitaxial layer, having a body top surface, a source embedded in the body, extending from the body top surface into the body, a gate trench extending into the epitaxial layer, a gate disposed in the gate trench, an active region contact trench extending through the source and into the body, an active region contact electrode disposed within the active region contact trench, wherein a thin layer of body region separating the active region contact electrode from the drain.

Abstract: A method for fabricating a power transistor includes: (a) forming a trench in a substrate with a first electrical type; (b) diffusing second electrical type carriers into the substrate from the trench such that the substrate is formed into a first part and a second part that is diffused with the second electrical type carriers and that adjoins the trench, the first and second parts being crystal lattice continuous to each other; (c) forming a filling portion in the trench, the filling portion adjoining the second part; (d) performing a carrier-implanting process in the second part and the filling portion; and (e) forming over the substrate a gate structure that has a dielectric layer and a conductive layer.

Abstract: An LDMOSFET transistor (100) is provided which includes a substrate (101), an epitaxial drift region (104) in which a drain region (116) is formed, a first well region (107) in which a source region (112) is formed, a gate electrode (120) formed adjacent to the source region (112) to define a first channel region (14), and a grounded substrate injection suppression guard structure that includes a patterned buried layer (102) in ohmic contact with an isolation well region (103) formed in a predetermined upper region of the substrate so as to be spaced apart from the first well region (107) and from the drain region (116), where the buried layer (102) is disposed below the first well region (107) but not below the drain region (116).

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

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

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

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

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

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

Abstract: A method for manufacturing a semiconductor device including a vertical double-diffusedmetal-oxide-semiconductor (VDMOS) transistor includes preparing a semiconductor substrate and injecting a first impurity of a second conductivity type to a first region, injecting a second impurity to a second region that is located inside and is narrower than the first region, and forming an epitaxial layer on the semiconductor substrate and forming the semiconductor layer constituted by the semiconductor substrate and the epitaxial layer, and at a same time, diffusing the first and the second impurities injected in a first impurity injection and a second impurity injection to form a buried layer of the second conductivity type.

Abstract: Disclosed is a method of forming a semiconductor device with drift regions of a first doping type and compensation regions of a second doping type, and a semiconductor device with drift regions of a first doping type and compensation regions of a second doping type.

Abstract: A component has a device applied to a device carrier, a first conducting layer grown onto the device and onto the device carrier, and an insulating material applied to the first conducting layer such that only a portion of the first conducting layer is covered.

Abstract: A method and system for fabricating a stacked capacitor and a DMOS transistor are disclosed. In one aspect, the method and system include providing a bottom plate, an insulator, and an additional layer including first and second plates. The insulator covers at least a portion of the bottom plate and resides between the first and second top plates and the bottom plate. The first and second top plates are electrically coupled through the bottom plate. In another aspect, the method and system include forming a gate oxide. The method and system also include providing SV well(s) after the gate oxide is provided. A portion of the SV well(s) resides under a field oxide region of the device. Each SV well includes first, second, and third implants having a sufficient energy to provide the portion of the SV well at a desired depth under the field oxide region without significant additional thermal processing. A gate, source, and drain are also provided.

Abstract: An impurity buried layer constructed by two buried regions formed by impurities of identical type exist, a buried region formed by an impurity having a slow diffusion speed is provided on the entire surface of a transistor formation region, and a buried region formed by an impurity having a fast diffusion speed is provided inwardly from beneath the inside end of an isolation insulating film serving as a region on which an electric field concentrates partially.

Abstract: According to one embodiment, a semiconductor device including a cell region and a terminal region includes a first semiconductor region of a first conductivity type, semiconductor pillars of the first and a second conductivity type, a second semiconductor region of the second conductivity type, and a third semiconductor region of the first conductivity type. The semiconductor pillars of the first and second conductivity type are and arranged alternately on the first semiconductor region. The second semiconductor region is provided on the semiconductor pillar of the second conductivity type. The third semiconductor region is provided on the second semiconductor region. A semiconductor pillar other than a semiconductor pillar most proximal to the terminal region is provided in a stripe configuration. The semiconductor pillar most proximal to the terminal region includes regions having a high and a low impurity concentration. The regions are provided alternately.

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

Abstract: A power semiconductor device having adjustable output capacitance includes a semiconductor substrate having a first device region and a second device region defined thereon, at lest one power transistor device disposed in the first device region, a heavily doped region disposed in the semiconductor substrate of the second device region, a capacitor dielectric layer disposed on the heavily doped region, a source metal layer disposed on a top surface of the semiconductor substrate and electrically connected to the power transistor device, and a drain metal layer disposed on a bottom surface of the semiconductor substrate. The source metal layer in the second device, the capacitor dielectric layer and the heavily doped region form a snubber capacitor.

Abstract: A process manufactures a multi-drain power electronic device integrated on a semiconductor substrate of a first type of conductivity whereon a drain semiconductor layer is formed. The process includes: forming a first semiconductor epitaxial layer of the first type of conductivity of a first value of resistivity forming the drain epitaxial layer on the semiconductor substrate, forming first sub-regions of a second type of conductivity by a first selective implant step with a first implant dose, forming second sub-regions of the first type of conductivity by a second implant step with a second implant dose, and forming a surface semiconductor layer. The process also includes forming body regions of the second type of conductivity aligned with the first sub-regions, and carrying out a thermal diffusion process so that the first sub-regions form a single electrically continuous column region aligned and in electric contact with the body regions.

Abstract: A device includes an array of cells, the source regions of the individual cells comprising a plurality of source region branches each extending towards a source region branch of an adjacent cell, the base regions of the individual cells comprising a corresponding plurality of base region branches merging together to form a single base region surrounding the source regions. The junctions between the merged base region and the drain region define rounded current conduction path areas for the on-state of the device between adjacent cells. Floating voltage regions of opposite conductivity type to the drain region are buried in the substrate beneath the merged base region. The features of the floating voltage regions define rings of the opposite conductivity type to the drain region that surround the current conduction paths of respective cells. The floating voltage regions include respective islands situated within the current conduction paths.

Abstract: Each unit cell includes: a drift layer 3 made of an n-type wide bandgap semiconductor formed on a substrate 2 made of an n-type wide bandgap semiconductor; a p-type well 4a provided in the driwhoseft layer 3; a first n-type impurity region 5 provided in the well 4a; a surface channel layer 7b formed at least on a surface of the well so as to connect together the first n-type impurity region 5 and the drift layer 3; a second n-type impurity region 7a provided in a surface region of the well which is under the surface channel layer and which spans the first n-type impurity region 5 and the drift layer 3, the second n-type impurity region 7a having an impurity concentration generally equal to or greater than an impurity concentration of the well 4a; and a third n-type impurity region formed in a surface region of the drift layer 3 adjacent to the second n-type impurity region 7a.

Abstract: High-mobility vertical trench DMOSFETs and methods for manufacturing are disclosed. A source region, a drain region or a channel region of a high-mobility vertical trench DMOSFET may comprise silicon germanium (SiGe) that increases the mobility of the charge carriers in the channel region. In some embodiments the channel region may be strained to increase channel charge carriers mobility.

Abstract: Provided are a semiconductor device which can shorten reverse recovery time without increasing leakage current between the drain and the source, and a fabrication method for such semiconductor device.

Abstract: Self-aligned charge balanced semiconductor devices and methods for forming such devices are disclosed. One or more planar gates are formed over a semiconductor substrate of a first conductivity type. One or more deep trenches are etched in the semiconductor self-aligned to the planar gates. The trenches are filled with a semiconductor material of a second conductivity type such that the deep trenches are charge balanced with the adjacent regions of the semiconductor substrate This process can form self-aligned charge balanced devices with a cell pitch less than 12 microns.

Abstract: A semiconductor device includes a drift zone of a first conductivity type formed within a semiconductor body, wherein one side of opposing sides of the drift zone adjoins a first zone within the semiconductor body and the other side adjoins a second zone within the semiconductor body. First semiconductor subzones of a second conductivity type different from the first conductivity type are formed within each of the first and second zones opposing each other along a lateral direction extending parallel to a surface of the semiconductor body. A second semiconductor subzone is formed within each of the first and second zones and between the first semiconductor subzones along the lateral direction. An average concentration of dopants within the second semiconductor subzone along 10% to 90% of an extension of the second semiconductor subzone along a vertical direction perpendicular to the surface is smaller than the average concentration of dopants along a corresponding section of extension within the drift zone.

Abstract: A semiconductor device includes a semiconductor layer of a first conductivity type and a first doping concentration. A first semiconductor region, used as drain, of the first conductivity type has a lower doping concentration than the semiconductor layer and is over the semiconductor layer. A gate dielectric is over the first semiconductor region. A gate electrode over the gate dielectric has a metal-containing center portion and first and second silicon portions on opposite sides of the center portion. A second semiconductor region, used as a channel, of the second conductivity type has a first portion under the first silicon portion and the gate dielectric. A third semiconductor region, used as a source, of the first conductivity type is laterally adjacent to the first portion of the second semiconductor region. The metal-containing center portion, replacing silicon, increases the source to drain breakdown voltage.

Abstract: A staggered column superjunction semiconductor device may include a cell region having one or more device cells. One or more device cells in the cell region include a semiconductor substrate configured to act as a drain and a semiconductor layer formed on the substrate. A first doped column may be formed in the semiconductor layer to a first depth and a second doped column may be formed in the semiconductor layer to a second depth. The first depth is greater than the second depth. The first and second columns are doped with dopants of a same second conductivity type and extend along a portion of a thickness of the semiconductor layer and are separated from each by a portion of the semiconductor layer.

Abstract: A power semiconductor element having a lightly doped drift and buffer layer is disclosed. One embodiment has, underneath and between deep well regions of a first conductivity type, a lightly doped drift and buffer layer of a second conductivity type. The drift and buffer layer has a minimum vertical extension between a drain contact layer on the adjacent surface of a semiconductor substrate and the bottom of the deepest well region which is at least equal to a minimum lateral distance between the deep well regions. The vertical extension can also be determined such that a total amount of dopant per unit area in the drift and buffer layer is larger than a breakdown charge amount at breakdown voltage.

Abstract: This invention discloses a method for manufacturing a semiconductor power device in a semiconductor substrate comprises an active cell area and a termination area.

Abstract: A disclosed power transistor, suitable for use in a switch mode converter that is operable with a switching frequency exceeding, for example, 5 MHz or more, includes a gate dielectric layer overlying an upper surface of a semiconductor substrate and first and second gate electrodes overlying the gate dielectric layer. The first gate electrode is laterally positioned overlying a first region of the substrate. The first substrate region has a first type of doping, which may be either n-type or p-type. A second gate electrode of the power transistor overlies the gate dielectric and is laterally positioned over a second region of the substrate. The second substrate region has a second doping type that is different than the first type. The transistor further includes a drift region located within the substrate in close proximity to an upper surface of the substrate and laterally positioned between the first and second substrate regions.

Abstract: Described is a method for fabricating a semiconductor device having an FET of a trench-gate structure obtained by disposing a conductive layer, which will be a gate, in a trench extended in the main surface of a semiconductor substrate, wherein the upper surface of the trench-gate conductive layer is formed equal to or higher than the main surface of the semiconductor substrate. In addition, the conductive layer of the trench gate is formed to have a substantially flat or concave upper surface and the upper surface is formed equal to or higher than the main surface of the semiconductor substrate. Moreover, after etching of the semiconductor substrate to form the upper surface of the conductive layer of the trench gate equal to or higher than the main surface of the semiconductor substrate, a channel region and a source region are formed by ion implantation. The semiconductor device thus fabricated according to the present invention is free from occurrence of a source offset.