Abstract: A semiconductor substrate comprises epitaxial region, body region and source region; an array of interdigitated active nitride-capped trench gate stacks (ANCTGS) and self-guided contact enhancement plugs (SGCEP) disposed above the semiconductor substrate and partially embedded into the source region, the body region and the epitaxial region forming the trench-gated MOSFET array.

Abstract: In one implementation, a trench field-effect transistor (trench FET) includes a semiconductor substrate having a drain region, a drift zone over the drain region, and depletion trenches formed over the drain region. Each depletion trench includes a depletion trench dielectric and a depletion electrode. The trench FET can further include a respective bordering gate trench situated alongside each depletion trench, each bordering gate trench having a gate electrode and a gate dielectric. The gate dielectric is merged with the depletion trench dielectric between the depletion electrode and the gate electrode.

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

Abstract: Semiconductor power devices such as vertical FPMOS are described preferably having a plurality of trenches formed at a top portion of a semiconductor substrate extending laterally across the semiconductor substrate along a longitudinal direction. Each trench has sidewalls generally perpendicular to a longitudinal direction of the trench and extending downward from a top surface to a trench bottom. Gate electrodes and source electrodes are positioned in the trenches with controlled spacing between their surfaces to achieve increased capacitance between them at increasing depth from the top surface. This provides higher frequency performance at higher power levels while improving tolerance to higher voltage.

Abstract: A semiconductor device includes a substrate including first to third fins aligned in a first direction, a first trench arranged between the first fin and the second fin, and a second trench arranged between the second fin and the third fin. The semiconductor device further includes a first field insulating film arranged in the first trench, a second field insulating film formed in the second trench, a first dummy gate arranged on the first field insulating film, and a second dummy gate at least partly arranged on the second field insulating film. A lower surface of the second field insulating film is arranged to be lower than a lower surface of the first field insulating film.

Abstract: An integrated circuit device according to an embodiment includes a semiconductor substrate, a first semiconductor member and a second semiconductor member provided on the semiconductor substrate, a first electrode disposed between the first semiconductor member and the second semiconductor member, and a second electrode disposed between the semiconductor substrate and the first electrode. The first semiconductor member and the second semiconductor member extend in a first direction perpendicular to an upper surface of the semiconductor substrate. The first semiconductor member and the second semiconductor member are separated in a second direction orthogonal to the first direction. The first electrode extends in a third direction intersecting both the first direction and the second direction. The second electrode extends in the third direction.

Abstract: A field plate trench transistor having a semiconductor body. In one embodiment the semiconductor has a trench structure and an electrode structure embedded in the trench structure. The electrode structure being electrically insulated from the semiconductor body by an insulation structure and having a gate electrode structure and a field electrode structure. The field plate trench transistor has a voltage divider configured such that the field electrode structure is set to a potential lying between source and drain potentials.

Abstract: Disclosed are field effect transistor (FET) formation methods using a final gate cut process and the resulting structures. One method forms an elongated gate across first and second semiconductor bodies for first and second FETs, respectively. An opening is formed in a portion of the elongated gate between the semiconductor bodies, cutting at least the gate conductor layer. The opening is filled with an isolation layer, thereby forming an isolation region that segments the elongated gate into first and second gates for the first and second FETs, respectively. Another method forms at least three gates across an elongated semiconductor body. An isolation region is formed that extends, not only through a portion of a center one of the gates, but also through a corresponding portion of the elongated semiconductor body adjacent to that gate, thereby segmenting the elongated semiconductor body into discrete semiconductor bodies for first and second FETs.

Abstract: A power semiconductor device having low on-state resistance includes a substrate having an epitaxial layer formed thereon, a gate structure, a termination structure, and a patterned conductive layer. The epitaxial layer has at least a first trench and a second trench. The gate structure is embedded in the first trench, including a gate electrode and a shielding electrode disposed under the gate electrode. The termination structure is embedded in the second trench, including a termination electrode. The patterned conductive layer is disposed above the epitaxial layer. Specially, the shield electrode of the gate structure and the termination electrode of the termination structure are configured to receive the gate voltage. The patterned conductive layer is configured to electrically contact said gate electrode and termination electrodes by a first contact plug and a second contact plug respectively.

Abstract: A semiconductor device includes a substrate, a first active fin and a second active fin on the substrate, respectively, a plurality of first epitaxial layers on the first active fin and on the second active fin, respectively, a plurality of second epitaxial layers on the plurality of first epitaxial layers, a bridge layer connecting the plurality of second epitaxial layers to each other, and a third epitaxial layer on the bridge layer.

Abstract: The present disclosure relates to a superjunction device and a semiconductor structure having the same. The superjunction device includes a body region of a second conduction type, a drain region of a first conduction type, a drift region located between said body region and said drain region. The drift region includes first regions of a first conduction type and second regions of a second conduction type arranged alternately along a direction being perpendicular to the direction from the body region to the drain region, and a plurality of trench gate structures, each of them comprising a trench extending into said drift region from an upper surface of said body region and a gate electrode in said trench surrounded by a first dielectric layer filling said trench, and a source region of a first conduction type embedded into said body region. There is no source region along at least 10% of the total interface length between the first dielectric layer and the body region.

Abstract: One embodiment of a semiconductor device includes a dense trench transistor cell array. The dense trench transistor cell array includes a plurality of transistor cells in a semiconductor body. A width w3 of a transistor mesa region of each of the plurality of transistor cells and a width w1 of a first trench of each of the plurality of transistor cells satisfy the following relationship: w3<1.5×w1. The semiconductor device further includes semiconductor diodes. At least one of the semiconductor diodes is arranged between first and second parts of the plurality of transistor cells and includes a diode mesa region adjoining opposing walls of second trenches. A depth d1 of the first trench and a depth d2 of the second trenches differ by at least 20%.

Abstract: A first sacrificial gate structure of a first width and a second sacrificial gate structure of a second width greater than the first width are provided on a semiconductor material portion. A dielectric spacer and a planarizing dielectric material are provided surrounding each sacrificial gate structure. Each sacrificial gate structure is then removed forming gate cavities. A high k dielectric material, a metal nitride hard mask and a physical vapor deposited (PVD) amorphous-silicon cap are provided. Vertical portions of the metal nitride hard mask and the high k dielectric material are removed from a portion of each gate cavity. Additional PVD amorphous silicon is then deposited and then all amorphous silicon and remaining metal nitride hard mask portions are removed. A work function portion having a stair-like surface, a diffusion barrier portion, a conductive metal structure and a dielectric cap are then formed into to each of the gate cavities.

Abstract: Methods of fabricating vertical devices are described, along with apparatuses and systems that include them. In one such method, a vertical device is formed at least partially in a void in a first dielectric material and a second dielectric material. Additional embodiments are also described.

Abstract: At least three electrically conducting blocks are disposed within an isolating region; and at least two of them are mutually separated and capacitively coupled by a part of the isolating region. At least two of them, being semiconductor, have opposite types of conductivity or identical types of conductivity, but with different concentrations of dopants, and these are in mutual contact by one of their sides. The mutual arrangement of these blocks within the isolating region, their type of conductivity and their concentration of dopants form at least one electronic module. Some of the blocks define input and output blocks.

Abstract: Resistive random access memory elements, such as phase change memory elements, may be defined using a plurality of parallel conductive lines over a stack of layers, at least one of which includes a resistive switching material. The stack may be etched using the conductive lines as a mask. As a result, memory elements may be self-aligned to the conductive lines.

Abstract: A semiconductor device includes: a first semiconductor region; a second semiconductor region; a third semiconductor region; a fourth semiconductor region; an insulation film, which is arranged on an inner wall of a recess extending from an upper surface to the second semiconductor region; a control electrode, which is arranged on a region of the insulation film on a side surface of the recess; a first main electrode connected to the first semiconductor region; a second main electrode connected to the fourth semiconductor region; and a bottom electrode, which is arranged on the insulation film and is electrically connected to the second main electrode, and a length of the recess in an extension direction thereof is equal to or larger than a width of the recess, and the width of the recess is wider than an interval between the adjacent recesses.

Abstract: A method for operating a field-effect transistor having a source terminal, a drain terminal, a gate terminal, a drift region and a dielectric region adjoining the drift region, is provided. The method includes: connecting at least one of the drain terminal and the source terminal to a load; applying a sequence of voltage pulses between the gate terminal and the source terminal to repetitively switch the field-effect transistor such that the field-effect transistor is driven in an avalanche mode between the voltage pulses, during the avalanche mode avalanche multiplication occurring in the drift region close to the dielectric region; and applying at least one relaxation pulse to the field-effect transistor to reduce an accumulation of charges in the dielectric region due to hot charge carriers generated in the avalanche mode. Further, a field-effect transistor and a circuit configuration including the field-effect transistor are provided.

Abstract: A semiconductor device (A1) includes a semiconductor layer having a first face with a trench (3) formed thereon and a second face opposite to the first face, a gate electrode (41), and a gate insulating layer (5). The semiconductor layer includes a first n-type semiconductor layer (11), a second n-type semiconductor layer (12), a p-type semiconductor layer (13), and an n-type semiconductor region (14). The trench (3) is formed so as to penetrate through the p-type semiconductor layer (13) and to reach the second n-type semiconductor layer (12). The p-type semiconductor layer (13) includes an extended portion extending to a position closer to the second face of the semiconductor layer than the trench (3) is. Such structure allows suppressing dielectric breakdown in the gate insulating layer (5).

Abstract: Neutron-detecting structures and methods of fabrication are provided which include: a substrate with a plurality of cavities extending into the substrate from a surface; a p-n junction within the substrate and extending, at least in part, in spaced opposing relation to inner cavity walls of the substrate defining the plurality of cavities; and a neutron-responsive material disposed within the plurality of cavities. The neutron-responsive material is responsive to neutrons absorbed for releasing ionization radiation products, and the p-n junction within the substrate spaced in opposing relation to and extending, at least in part, along the inner cavity walls of the substrate reduces leakage current of the neutron-detecting structure.

Abstract: A method of making a split gate non-volatile memory (NVM) using a substrate includes etching a recess into an isolation region of an NVM region of the substrate and depositing a conductive layer and a capping layer. A select gate and a control gate are formed in the NVM region, and a dummy gate is formed in a logic region of the substrate. A portion of the capping layer is removed and a salicide block bi-layer is deposited and patterned to form a first opening that exposes a contact portion of the conductive layer over the recess. A silicided region is formed on the contact portion. The substrate is planarized to expose the dummy gate, which is replaced with a metal gate. A second opening is etched through a first interlayer dielectric deposited over the substrate to the silicided region. Contact metal is deposited into the second opening.

Abstract: A super junction structure having implanted column regions surrounding an N epitaxial layer in a deep trench is disclosed to overcome charge imbalance problem and to further reduce Rds. The inventive super junction can be used for MOSFET and Schottky rectifier.

Abstract: Provided is a semiconductor device that can be manufactured at low cost and that can reduce a reverse leak current, and a manufacturing method thereof. A semiconductor device has: a source region and a drain region having a body region therebetween; a source trench that reaches the body region, penetrating the source region; a body contact region formed at the bottom of the source trench; a source electrode embedded in the source trench; and a gate electrode that faces the body region. The semiconductor device also has: an n-type region for a diode; a diode trench formed reaching the n-type region for a diode; a p+ region for a diode that forms a pn junction with the n-type region for a diode at the bottom of the diode trench; and a schottky electrode that forms a schottky junction with the n-type region for a diode at side walls of the diode trench.

Abstract: One method disclosed includes, among other things, forming an initial fin, covering a top surface and a portion of the sidewalls of the initial fin structure with etch stop material, forming a sacrificial gate structure above and around the initial fin structure, forming a sidewall spacer adjacent the sacrificial gate structure, performing at least one process operation to remove the sacrificial gate structure and thereby define a replacement gate cavity, performing at least one etching process through the replacement gate cavity to remove a portion of the initial fin structure so as to thereby define a final fin structure and a channel cavity positioned below the final fin structure, and substantially filling the channel cavity with an insulating material.

Abstract: A semiconductor device includes: a first semiconductor region; a second semiconductor region, which is arranged on the first semiconductor region; a third semiconductor region, which is arranged on the second semiconductor region; a plurality of fourth semiconductor regions, each of which is arranged with being spaced from each other on the third semiconductor region; a insulation film arranged on a inner wall of a recess, which extends from upper faces of the fourth semiconductor region to pass through the third semiconductor region and the fourth semiconductor region and reaches the second semiconductor region; a control electrode, a first main electrode, a second main electrode, which is electrically connected to the third semiconductor region and the fourth semiconductor region, wherein a ratio of a width of the recess to a width of the third semiconductor region abutting on the second main electrode is 1 or more.

Abstract: A semiconductor device includes a first gate electrode that is provided on a first insulating film along one side wall of a first trench and is provided in a second trench, a shield electrode that is provided on a second insulating film along the other side wall of the first trench and is provided in a third trench, a gate runner that is an extended portion of the second trench, has a portion which is provided on the first gate electrode, and is connected to the first gate electrode, and an emitter polysilicon layer that is an extended portion of the third trench, has a portion which is provided on the shield electrode, and is connected to the shield electrode. The semiconductor device has improved turn-on characteristics with a slight increase in the number of process steps, while preventing increase in costs and reduction in yield.

Abstract: A method of manufacturing an insulated gate bipolar transistor (IGBT) device comprising 1) preparing a semiconductor substrate with an epitaxial layer of a first conductivity type supported on the semiconductor substrate of a second conductivity type; 2) applying a gate trench mask to open a first trench and second trench followed by forming a gate insulation layer to pad the trench and filling the trench with a polysilicon layer to form the first trench gate and the second trench gate; 3) implanting dopants of the first conductivity type to form an upper heavily doped region in the epitaxial layer; and 4) forming a planar gate on top of the first trench gate and apply implanting masks to implant body dopants and source dopants to form a body region and a source region near a top surface of the semiconductor substrate.

Abstract: A semiconductor device includes first and second gate electrode structures and a connection plug. The first gate electrode structure is buried in a semiconductor portion and has array stripes inside a first cell array of transistor cells and a contact stripe outside the first cell array, the contact stripe structurally connected with the array stripes. The second gate electrode structure is buried in the semiconductor portion and has array stripes inside a second cell array of transistor cells. An array isolation region of the semiconductor portion separates the first and second gate electrode structures. The connection plug extends between a first surface of the semiconductor portion and the contact stripe of the first gate electrode structure.

Abstract: A semiconductor device of an embodiment includes a first conductive type silicon carbide substrate having first and second main surfaces, a first conductive type silicon carbide layer formed on the first main surface, a second conductive type first silicon carbide region formed in the silicon carbide layer, and a first conductive type second silicon carbide region formed in the first silicon carbide region. The device includes a trench penetrating through the first and second silicon carbide regions, and a second conductive type third silicon carbide region formed on a bottom and a side surface of the trench. The third silicon carbide region is in contact with the first silicon carbide region, and is formed between the trench and the silicon carbide layer. In addition, the device includes a gate insulating film formed in the trench, a gate electrode, a first electrode, and a second electrode.

Abstract: A semiconductor device may include, but is not limited to, a semiconductor substrate having a first gate groove; a first fin structure underneath the first gate groove; a first diffusion region in the semiconductor substrate, the first diffusion region covering an upper portion of a first side of the first gate groove; and a second diffusion region in the semiconductor substrate. The second diffusion region covers a second side of the first gate groove. The second diffusion region has a bottom which is deeper than a top of the first fin structure.

Abstract: An oxide termination semiconductor device may comprise a plurality of gate trenches, a gate runner, and an insulator termination trench. The gate trenches are located in an active region. Each gate trench includes a conductive gate electrode. The insulator termination trench is located in a termination region that surrounds the active region. The insulator termination trench is filled with an insulator material to form an insulator termination for the semiconductor device. Source and body regions inside the active region are at source potential and source and body regions outside the isolation trench are at drain potential. The device can be made using a three-mask or four-mask process.

Abstract: A semiconductor device includes a field effect transistor structure having source zones of a first conductivity type and body zones of a second conductivity type which is the opposite of the first conductivity type, the source zones adjoining a first surface of a semiconductor die comprising the source and the body zones. The semiconductor device further includes a dielectric layer adjoining the first surface and polysilicon plugs extending through openings in the dielectric layer and electrically connected to the source and the body zones. The polysilicon plugs have silicide crystallites in portions distant to the semiconductor die.

Abstract: A transistor component includes a semiconductor body, a first main electrode, a gate contact electrode, a plurality of transistor cells, and a plurality of gate electrodes. The semiconductor body has a drain region and a drift region of a first conduction type, and a body region of a second conduction type. The first main electrode is on a top side of the semiconductor body. The plurality of gate electrodes is electrically connected to the gate contact electrode and arranged successively in a first lateral direction. In the plurality, a first gate electrode is next to a second gate electrode. The first main electrode includes a first trench contact finger, between the first gate electrode and the second gate electrode, and a second trench contact finger, between the first gate electrode and the second gate electrode, electrically connecting the first main electrode to the body region.

Abstract: A semiconductor device comprises a transistor formed in a semiconductor body having a first main surface. The transistor comprises a source region, a drain region, a channel region, a drift zone, a source contact electrically connected to the source region, a drain contact electrically connected to the drain region, and a gate electrode at the channel region. The channel region and the drift zone are disposed along a first direction between the source region and the drain region, the first direction being parallel to the first main surface. The channel region has a shape of a first ridge extending along the first direction. One of the source contact and the drain contact is adjacent to the first main surface, the other one of the source contact and the drain contact is adjacent to a second main surface that is opposite to the first main surface.

Abstract: A trench power MOSFET structure and fabrication method thereof is provided. The fabrication method comprises following process. First, form an isolating trench. Then, form at least two doped regions around the isolating trench. The doped regions are adjacent and the doping concentrations of two doped regions are different. Form an isolating structure in the isolating trench. Wherein, the junction profiles of the two doped regions are made by on implantation method for moderate the electric field distribution and decreasing the conduction loss.

Abstract: A trench groove is formed and a silicon oxide film is buried in the periphery of a channel region of (0001) surface 4h-SiC semiconductor element. The oxide film in the trench groove is defined in such a planar layout that a tensile strain is applied along the direction of the c-axis and a compressive strain is applied along two or more of axes on a plane perpendicular to the c-axis. For example, trench grooves buried with an oxide film may be configured to such a layout that they are in a trigonal shape surrounding the channel, or are arranged symmetrically with respect to the channel as a center when arranged discretely.

Abstract: A vertical transistor component includes a semiconductor body with first and second surfaces, a drift region, and a source region and body region arranged between the drift region and the first surface. The body region is also arranged between the source region and the drift region. The vertical transistor component further includes a gate electrode arranged adjacent to the body zone, a gate dielectric arranged between the gate electrode and the body region, and a drain region arranged between the drift region and the second surface. A source electrode electrically contacts the source region, is electrically insulated from the gate electrode and arranged on the first surface. A drain electrode electrically contacts the drain region and is arranged on the second surface. A gate contact electrode is electrically insulated from the semiconductor body, extends in the semiconductor body to the second surface, and is electrically connected with the gate electrode.

Abstract: The present disclosure relates to a superjunction device and a semiconductor structure having the same. The superjunction device includes a body region of a second conduction type, a drain region of a first conduction type, a drift region located between said body region and said drain region. The drift region includes first regions of a first conduction type and second regions of a second conduction type arranged alternately along a direction being perpendicular to the direction from the body region to the drain region, and a plurality of trench gate structures, each of them comprising a trench extending into said drift region from an upper surface of said body region and a gate electrode in said trench surrounded by a first dielectric layer filling said trench, and a source region of a first conduction type embedded into said body region. There is no source region along at least 10% of the total interface length between the first dielectric layer and the body region.

Abstract: A power semiconductor device with improved avalanche capability is disclosed by forming at least one avalanche capability enhancement doped region underneath an ohmic contact doped region. Moreover, a source mask is saved by using three masks process and the avalanche capability is further improved.

Abstract: A fin field effect transistor (fin FET) is formed using a bulk silicon substrate and sufficiently guarantees a top channel length formed under a gate, by forming a recess having a predetermined depth in a fin active region and then by forming the gate in an upper part of the recess. A device isolation film is formed to define a non-active region and a fin active region in a predetermined region of the substrate. In a portion of the device isolation film a first recess is formed, and in a portion of the fin active region a second recess having a depth shallower than the first recess is formed. A gate insulation layer is formed within the second recess, and a gate is formed in an upper part of the second recess. A source/drain region is formed in the fin active region of both sides of a gate electrode.

Abstract: A semiconductor device has an epitaxial layer grown over a substrate, each having a first dopant type. A structure disposed within the epitaxial layer has multiple trenches, each of which has a gate and a source electrode disposed within a shield oxide matrix. Multiple mesas each isolate a pair of the trenches from each other. A body region with a second dopant type is disposed above the epitaxial layer and bridges each of the mesas. A region of elevated concentration of the first dopant type is implanted at a high energy level between the epitaxial layer and the body region, which reduces resistance spreading into a channel of the device. A source region having the first dopant type is disposed above the body region.

Abstract: In one embodiment, a semiconductor device includes an isolated trench-electrode structure. The semiconductor device is formed using a modified photolithographic process to produce alternating regions of thick and thin dielectric layers that separate the trench electrode from regions of the semiconductor device. The thin dielectric layers can be configured to control the formation channel regions, and the thick dielectric layers can be configured to reduce switching losses.

Abstract: An insulated gate field effect transistor configured to reduce the occurrence of a short-circuit fault, and a method of manufacturing the insulated gate field effect transistor are provided. A FET includes a semiconductor substrate, a gate insulator, a gate electrode, and a conductive member. The semiconductor substrate has an insulation groove that splits a channel region into a first channel region on a drain region side and a second channel region on a source region side. The conductive member is supported by a drain-side end face and a source-side end face of the insulation groove. When the temperature of the conductive member is equal to or higher than a predetermined temperature, the conductive member is cut.

Abstract: A transistor includes a semiconductor body; a body region of a first conductivity type formed in the semiconductor body; a gate electrode formed partially overlapping the body region and insulated from the semiconductor body by a gate dielectric layer; a source diffusion region of a second conductivity type formed in the body region on a first side of the gate electrode; a trench formed in the semiconductor body on a second side, opposite the first side, of the gate electrode, the trench being lined with a sidewall dielectric layer; and a doped sidewall region of the second conductivity type formed in the semiconductor body along the sidewall of the trench where the doped sidewall region forms a vertical drain current path for the transistor.

Abstract: A semiconductor device has a plurality of gate electrodes over a gate insulator layer formed in active trenches located in an active region of a semiconductor substrate. A first gate runner is formed in the semiconductor substrate and electrically connected to the gate electrodes. The first gate runner abuts and surrounds the active region. A second gate runner is connected to the first gate runner to make contact to a gate metal. A dielectric filled trench surrounds the first and second gate runners and the active region and a highly doped channel stop region is formed under the dielectric filled trench.

Abstract: Semiconductor device fabrication method and devices are disclosed. A device may be fabricated by forming in a semiconductor layer; filling the trench with an insulating material; removing selected portions of the insulating material leaving a portion of the insulating material in a bottom portion of the trench; forming one or more spacers on one or more sidewalls of a remaining portion of the trench; anisotropically etching the insulating material in the bottom portion of the trench using the spacers as a mask to form a trench in the insulator; removing the spacers; and filling the trench in the insulator with a conductive material. Alternatively, an oxide-nitride-oxide (ONO) structure may be formed on a sidewall and at a bottom of the trench and one or more conductive structures may be formed in a portion of the trench not occupied by the ONO structure.

Abstract: The present invention provides a semiconductor device designed to prevent an electric field from being concentrated in the vicinity of a groove portion. The semiconductor includes a semiconductor layer, a source region, a drain region, a source offset region, a drain offset region, a groove portion, a gate insulating film, a gate electrode, and an embedded region. The groove portion is provided in at least a position between the source offset region and the drain offset region in the semiconductor layer in a plan view, in a direction from the source offset region to the drain offset region in a plan view. The gate insulating film covers a side and a bottom of the groove portion. The gate electrode is provided only within the groove portion in a plan view, and contacts the gate insulating film.

Abstract: The present invention provides a dynamic random access memory (DRAM) including a plurality of transistors formed in a semiconductor substrate, wherein each of the transistors includes a vertical channel region. A plurality of bit line contained trenches is formed in the semiconductor substrate. Each of the bit line contained trenches comprises two bit lines, and each of the bit lines is electrically connected to an adjacent transistor. Each two sidewalls of each of the bit line contained trenches have a contact formed thereon. A plurality of word lines are formed over the plurality of bit lines and electrical connect to the plurality of transistors. Furthermore, a method for fabricating the DRAM is also provided.

Abstract: A method for forming a fin field-effect transistor (FinFET) device, comprises forming a plurality of silicon fins on a substrate, depositing silicon germanium (SiGe) on the plurality of fins, forming a gate region by forming a dummy gate stack on a predetermined area of the fins including the SiGe, removing the SiGe from an area of the fins not covered by the dummy gate stack, forming a merged region in the area of the fins not covered by the dummy gate stack to form a source drain region, removing the dummy gate stack to expose the remaining SiGe in the gate region, mixing the SiGe with the silicon fins in the gate region to form SiGe fins, and depositing a gate dielectric and gate metal on the SiGe fins.

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.