Abstract: An embodiment of a semiconductor device includes a transistor cell array having transistor cells in a semiconductor body. A planar gate structure is on the semiconductor body at a first side. Field electrode trenches extend into the semiconductor body from the first side. Each of the field electrode trenches includes a field electrode structure. A depth d of the field electrode trenches is greater than a maximum lateral dimension wmax of the field electrode trenches at the first side.

Abstract: A semiconductor device includes a semiconductor body, having a first surface, a gate electrode structure, which includes polycrystalline silicon, of an IGFET in a first trench extending from the first surface into the semiconductor body. The device also includes a semiconductor element, which is different from the gate electrode structure of the IGFET and includes polycrystalline silicon, in a second trench extending from the first surface into the semiconductor body, wherein the polycrystalline silicon of the IGFET and of the semiconductor element different therefrom ends below a top side of an insulation layer adjoining the first surface of the semiconductor body.

Abstract: A semiconductor device includes active pillars protruding from a semiconductor substrate and spaced apart from each other in a first direction and a second direction that is perpendicular to the first direction, a word line extending in the first direction between the active pillars, a drain region disposed in an upper portion of each of the active pillars, and a separation pattern provided between the word line and the drain region. A bottom surface of the separation pattern is disposed at a lower level than a bottom surface of the drain region.

Abstract: A method of forming a gate structure, including forming one or more vertical fins on a substrate; forming a bottom spacer on the substrate surface adjacent to the one or more vertical fins; forming a gate structure on at least a portion of the sidewalls of the one or more vertical fins; forming a gauge layer on at least a portion of the bottom spacer, wherein the gauge layer covers at least a portion of the gate structure on the sidewalls of the one or more vertical fins; and removing a portion of the gauge layer on the bottom spacer.

Abstract: A semiconductor device comprises a field effect transistor in a semiconductor substrate having a first main surface. The field effect transistor comprises a source region, a drain region, a body region, and a gate electrode at the body region. The gate electrode is configured to control a conductivity of a channel formed in the body region, and the gate electrode is disposed in gate trenches. The body region is disposed along a first direction between the source region and the drain region, the first direction being parallel to the first main surface. The body region has a shape of a ridge extending along the first direction, the body region being adjacent to the source region and the drain region. The semiconductor device further comprises a source contact and a body contact, the source contact being electrically connected to a source terminal, the body contact being electrically connected to the source contact and to the body region.

Abstract: The invention relates to a method for forming a field effect transistor. The method comprises providing a substrate with a channel layer, forming a gate stack structure on the channel layer, forming first sidewall spacers, forming a raised source and a raised drain on the channel layer and forming second sidewall spacers above the raised source and the raised drain. The method further includes depositing in a an insulating dielectric layer above the gate stack structure, the first sidewall spacers and the second sidewall spacers, planarization of the insulating dielectric layer and selectively etching the second sidewall spacers. Thereby contact cavities are created on the raised source and the raised drain. The method further includes forming a source contact and a drain contact by filling the contact cavities. The invention also concerns a corresponding computer program product.

Abstract: A split-gate flash memory cell for improved erase speed is provided. An erase gate and a floating gate are laterally spaced over a semiconductor substrate. The floating gate has a height increasing towards the erase gate, a concave sidewall surface neighboring the erase gate, and a tip defined an interface of the concave sidewall surface and an upper surface of the floating gate. A control gate and a sidewall spacer are arranged over the upper surface of the floating gate. The control gate is laterally offset from the tip of the floating gate, and the sidewall spacer is laterally arranged between the control gate and the tip. A method for manufacturing the split-gate flash memory cell is also provided.

Abstract: A semiconductor device includes a substrate comprising a source region and a drain region, a bit storing element formed on the substrate, a memory gate structure, a first insulating layer formed on the substrate, a second insulating layer formed on the substrate, and a select gate structure formed on the first insulating layer. The second insulating layer is formed on the memory gate structure and the select gate structure and between the memory gate structure and the select gate structure.

Abstract: A method for forming a semiconductor structure includes forming a trench in a semiconductor substrate; forming a gate dielectric layer over a bottom surface and sidewalls of the trench; forming a work function layer over the gate dielectric layer; recessing the work function layer, and forming a gate electrode which is positioned in the trench; and exposing the gate electrode to a thermal process, and forming a dipole induction layer between the gate electrode and the gate dielectric layer.

Abstract: A metal-oxide-semiconductor field effect transistor (MOSFET) includes a substrate and a gate structure over a top surface of the substrate. The MOSFET further includes a source in the substrate on a first side of the gate structure and a drain in the substrate on a second side of the gate structure opposite the first side. The gate structure includes a variable thickness gate dielectric layer. The variable thickness gate dielectric layer includes a first portion closest to the drain, the first portion having a first thickness. The variable thickness gate dielectric layer further includes a second portion distal from the drain, the second portion having a second thickness less than the first thickness.

Abstract: A semiconductor device and method of formation are provided. The semiconductor device includes a channel surrounding a dielectric tube and a gate surrounding the channel. The dielectric tube comprises a high dielectric constant material that has or conducts few to no carriers, such as electrons or holes. The presence of the dielectric tube confines carriers to the channel, which is in close proximity to the gate. The proximity of the channel, and the carriers therein, to the gate affords greater control to the gate over the carriers, thus allowing a length of the channel to be decreased while experiencing little to no short channel effects, such as current leakage through the channel.

Abstract: A method of forming a contact structure includes providing a silicon-carbide substrate having a highly doped silicon-carbide contact region formed in the substrate and extending to a main surface of the substrate. A carbon-based contact region is formed which is in direct contact with the highly doped silicon-carbide contact region and which extends to the main surface. A conductor is formed on the carbon-based contact region such that the carbon-based contact region is interposed between the conductor and the highly doped silicon-carbide contact region. A thermal budget for forming the carbon-based contact region is maintained below a level that induces metal silicidization of the highly doped silicon-carbide contact region.

Abstract: A device includes an n-doped InP layer and an ohmic contact, in contact with the n-doped InP layer. The ohmic contact includes an annealed stack of at least three, or preferably four alternating layers of Si and Ni, such that: (i) the n-doped InP layer and one of the layers of the stack in contact with the n-doped InP layer are at least partly intermixed; and (ii) any two adjacent layers of the stack are at least partly intermixed. Related fabrication methods are also disclosed.

Abstract: A method of manufacturing a field effect transistor using a gate last process includes providing the field effect transistor which includes a high-k dielectric formed between an elevated source and an elevated drain and surrounding a metal gate, and performing a chemical mechanical planarization (CMP) process on an upper surface of the elevated source, and in which a height of the metal gate becomes lower than a height of the elevated source according to the CMP process.

Abstract: A method includes forming a dummy gate of a transistor at a surface of a wafer, removing the dummy gate, and filling a metallic material into a trench left by the removed dummy gate. A Chemical Mechanical Polish (CMP) is then performed on the metallic material, wherein a remaining portion of the metallic material forms a metal gate of the transistor. After the CMP, a treatment is performed on an exposed top surface of the metal gate using an oxidation-and-etching agent comprising chlorine and oxygen.

Abstract: In a method of manufacturing a semiconductor device, an isolation pattern may be formed on a substrate to define a plurality of active patterns. The active patterns may protrude from the isolation pattern. A preliminary polysilicon layer may be formed on the active patterns to fill a gap between adjacent ones of the active patterns. Ions having no conductivity may be implanted into the preliminary polysilicon layer to form a polysilicon layer having no void. The active patterns maintain their crystalline state during the implanting of the ions. The polysilicon layer may be patterned to form a dummy gate structure on the active pattern. A source/drain region may be formed at an upper portion of the active patterns adjacent to sides of the dummy gate structure.

Abstract: A vertical field effect transistor includes a first source/drain region formed on or in a substrate. A tapered fin is formed a vertical device channel and has a first end portion attached to the first source/drain region. A second source/drain region is formed on a second end portion of the tapered fin. A gate structure surrounds the tapered fin.

Abstract: A method for forming a semiconductor device. In this method, a semiconductor fin is formed on a semiconductor substrate. Two cells adjacent to each other are formed on the semiconductor fin. A gate conductor is formed on a top of the semiconductor fin at a common boundary that is shared by the two cells. A gate spacer is formed to peripherally enclose the gate conductor. The gate conductor and the semiconductor fin are etched to form an air gap, thereby dividing the semiconductor fin into two portions of the semiconductor fin. A dielectric cap layer is deposited into the air gap to cap a top of the air gap.

Abstract: FinFET devices including III-V fin structures and silicon-based source/drain regions are formed on a semiconductor substrate. Silicon is diffused into the III-V fin structures to form n-type junctions. Leakage through the substrate is addressed by forming p-n junctions adjoining the source/drain regions and isolating the III-V fin structures under the channel regions.

Abstract: Devices and structures that include a gate spacer having a gap or void are described along with methods of forming such devices and structures. In accordance with some embodiments, a structure includes a substrate, a gate stack over the substrate, a contact over the substrate, and a spacer disposed laterally between the gate stack and the contact. The spacer includes a first dielectric sidewall portion and a second dielectric sidewall portion. A void is disposed between the first dielectric sidewall portion and the second dielectric sidewall portion.

Abstract: A method for manufacturing a semiconductor device comprises depositing alternating layers of a plurality of first dielectric layers and a plurality of second dielectric layers on a substrate in a stacked configuration, forming one or more first openings in the stacked configuration to a depth penetrating below an upper surface of a bottom second dielectric layer of the plurality of second dielectric layers, forming one or more second openings in the stacked configuration to a depth corresponding to an upper surface of the substrate or below an upper surface of the substrate, removing the plurality of second dielectric layers from the stacked configuration to form a plurality of gaps, and epitaxially growing a semiconductor material from a seed layer in the one or more second openings to fill the one or more first and second openings and the plurality of gaps, wherein defects caused by a lattice mismatch between the epitaxially grown semiconductor material and a material of the substrate are contained at a bot

Abstract: The present invention concerns a monolithically merged trenched-and-implanted Bipolar Junction Transistor (TI-BJT) with antiparallel diode and a method of manufacturing the same. Trenches are made in a collector, base, emitter stack downto the collector. The base electrode is formed on an implanted base contact region at the bottom surface of the trench. The present invention also provides for products produced by the methods of the present invention and for apparatuses used to perform the methods of the present invention.

Abstract: A superjunction bipolar transistor includes an active transistor cell area that includes active transistor cells electrically connected to a first load electrode at a front side of a semiconductor body. A superjunction area overlaps the active transistor cell area and includes a low-resistive region and a reservoir region outside of the low-resistive region. The low-resistive region includes a first superjunction structure with a first vertical extension with respect to a first surface of the semiconductor body. The reservoir region includes no superjunction structure or a second superjunction structure with a mean second vertical extension smaller than the first vertical extension.

Abstract: A semiconductor device includes: a first nitride semiconductor layer, a second nitride semiconductor layer that is provided on the first nitride semiconductor layer and has a band gap larger than a band gap of the first nitride semiconductor layer, a gate electrode that is provided on the first nitride semiconductor layer, a first electrode that is electrically connected to the first nitride semiconductor layer, a second electrode disposed such that the gate electrode is positioned between the first electrode and the second electrode, and electrically connected to the first nitride semiconductor layer, and a first insulation layer that is provided between the gate electrode and the second electrode, disposed such that the second nitride semiconductor layer is positioned between the first nitride semiconductor layer and the first insulation layer, and including silicon oxide having an oxygen-to-silicon atomic ratio (O/Si) of 1.50 or more and 1.85 or less.

Abstract: A semiconductor device is provided including a first electrode and a first semiconductor layer of a first conductivity type connected to the first electrode. The semiconductor device further includes a second semiconductor layer of a second conductivity type provided on the first semiconductor layer, a third semiconductor layer of the first conductivity type provided on the second semiconductor layer, and a second electrode provided on the third semiconductor layer. The semiconductor device further includes a third electrode disposed between the first electrode and the second electrode. The semiconductor device further includes a fourth electrode having an upper end connected to the second electrode, where the fourth electrode has a higher resistivity than the second electrode.

Abstract: Embodiments include a method and structure to that provide a clamping structure in an integrated semiconductor device. In accordance with an embodiment, the method includes forming trenches in a semiconductor material and forming a shield electrode in a portion of at least one of the trenches. A clamping structure is formed adjacent to a trench. The clamping structure has an electrode that may be electrically connected to a source region of the integrated semiconductor device. In accordance with another embodiment, an impedance element is formed in a trench.

Abstract: A semiconductor device according to the present invention includes a semiconductor layer provided with a gate trench, a first conductivity type source region formed to be exposed on a surface side of the semiconductor layer, a second conductivity type channel region formed on a side of the source region closer to a back surface of the semiconductor layer to be in contact with the source region, a first conductivity type drain region formed on a side of the channel region closer to the back surface of the semiconductor layer to be in contact with the channel region, a gate insulating film formed on an inner surface of the gate trench, and a gate electrode embedded inside the gate insulating film in the gate trench, while the channel region includes a channel portion formed along the side surface of the gate trench so that a channel is formed in operation and a projection projecting from an end portion of the channel portion closer to the back surface of the semiconductor layer toward the back surface.

Abstract: A semiconductor device includes transistor cells and control structures. The transistor cells include source zones of a first conductivity type and body zones of a second conductivity type. The source and body zones are formed in a semiconductor mesa formed from a portion of a semiconductor body. The control structures include first portions extending from a first surface into the semiconductor body on at least two opposing sides of the semiconductor mesa, second portions between the first portions and separated from the first surface by portions of the semiconductor mesa, and third portions connecting the first and the second portions and separated from the first surface by portions of the semiconductor mesa. Constricted sections of the semiconductor mesa separate third portions neighboring each other along a horizontal longitudinal extension of the semiconductor mesa.

Abstract: A semiconductor device comprising at least one active layer on a substrate and a first contact to the at least one active layer, the first contact comprising a metal in contact with the at least one active layer and a capping layer on the metal, the capping layer comprising a diffusion barrier, wherein the capping layer is patterned to form a pattern comprising regions of the contact covered by the capping layer and regions of the contact that are uncovered.

Abstract: A method of forming a fin structure that includes forming a plurality of fin structures from a bulk semiconductor substrate and forming a dielectric spacer on a sidewall of each fin structure in the plurality of fin structure. A semiconductor spacer is formed on a sidewall of the dielectric spacer. A dielectric fill is formed in the space between the adjacent fin structures. The semiconductor spacer and a portion of the fin structures that is present below a lower surface of the dielectric spacer are oxidized. Oxidizing a base portion of the fin structures produces a first strain and oxidizing the semiconductor spacer produces a second strain that is opposite the first strain.

Abstract: A method for detecting the presence and location of defects over a substrate is disclosed. In an embodiment, the method may include: forming a semiconductor material in a plurality of openings in a reference wafer using an epitaxial growth process; performing one or more measurements on the reference wafer to obtain a baseline signal; forming a plurality of gate stacks and stressor regions in a plurality of substrates; after forming the plurality of gate stacks, forming the semiconductor material in a plurality of openings in a batch wafer; performing the one or more measurements on the batch wafer to obtain a batch signal; comparing the batch signal to the baseline signal; and determining whether a defect in present in the plurality of substrates based on the comparison.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: Semiconductor devices and methods of manufacture thereof are disclosed. In a preferred embodiment, a method of manufacturing a semiconductor device includes providing a semiconductor wafer, forming a gate dielectric over the semiconductor wafer, and forming a gate over the gate dielectric. At least one recess is formed in the semiconductor wafer proximate the gate and the gate dielectric, at least a portion of the at least one recess extending beneath the gate. The at least one recess in the semiconductor wafer is filled with a semiconductive material.

Abstract: A method includes forming an isolation feature in a semiconductor substrate; forming a first fin-like active region and a second fin-like active region in the semiconductor substrate and interposed by the isolation feature; forming a dummy gate stack on the isolation feature, wherein the dummy gate extends to the first fin-like active region from one side and to the second fin-like active region from another side.

Abstract: A method of growing III-N semiconducting material on a silicon substrate including the steps of growing a layer of epitaxial rare earth oxide on a single crystal silicon substrate and modifying the surface of the layer of epitaxial rare earth oxide with nitrogen plasma. The method further includes the steps of growing a layer of low temperature epitaxial gallium nitride on the modified surface of the layer of epitaxial rare earth oxide and growing a layer of bulk epitaxial III-N semiconductive material on the layer of low temperature epitaxial gallium nitride.

Abstract: A self-aligned SiGe FinFET device features a relaxed channel region having a high germanium concentration. Instead of first introducing germanium into the channel and then attempting to relax the resulting strained film, a relaxed channel is formed initially to accept the germanium. In this way, a presence of germanium can be established without straining or damaging the lattice. Gate structures are patterned relative to intrinsic silicon fins, to ensure that the gates are properly aligned, prior to introducing germanium into the fin lattice structure. After aligning the gate structures, the silicon fins are segmented to elastically relax the silicon lattice. Then, germanium is introduced into the relaxed silicon lattice, to produce a SiGe channel that is substantially stress-free and also defect-free. Using the method described, concentration of germanium achieved in a structurally stable film can be increased to a level greater than 85%.

Abstract: A semiconductor device includes a fin patterned in a substrate; a gate disposed over and substantially perpendicular to the fin; a pair of epitaxial contacts including a III-V material over the fin and on opposing sides of the gate; and a channel region between the pair of epitaxial contacts under the gate including an undoped III-V material between doped III-V materials, the doped III-V materials including a dopant in an amount in a range from about 1e18 to about 1e20 atoms/cm3 and contacting the epitaxial contacts.

Abstract: A semiconductor device includes a fin structure comprising a cylindrical shape and including a recess formed in an upper surface of the fin structure, an inner gate formed inside the fin structure, an outer gate formed outside the fin structure, and a conductor formed in the recess and connecting the inner and outer gates.

Abstract: An object is to provide a method for manufacturing a semiconductor device without exposing a specific layer to moisture or the like at all. A thin film element is manufactured in such a manner that a first film, a second film, and a third film are stacked in this order; a resist mask is formed over the third film; a mask layer is formed by etching the third film with the use of the resist mask; the resist mask is removed; a second layer and a first layer are formed by performing dry etching on the second film and the first film with the use of the mask layer; a fourth film is formed to cover at least the second layer and the first layer; and sidewall layers are formed to cover at least the entire side surfaces of the first layer by performing etch back on the fourth film.

Abstract: The present disclosure provides an array substrate, a manufacturing method thereof and a display device. The array substrate includes an active layer, a gate insulating layer and a gate electrode layer formed sequentially on a base substrate. The active layer includes a first heavily-doped region, a first lightly-doped region, a first non-doped region, a second lightly-doped region, a second non-doped region, a third lightly-doped region and a second heavily-doped region which are sequentially arranged in a horizontal direction.

Abstract: A method for forming a semiconductor device includes etching a semiconductor layer using a gate structure and spacers as a mask to protect portions of the semiconductor layer that extend beyond the gate structure. Undercuts are formed in a buried dielectric layer under the gate structure. Source and drain regions are epitaxially growing and wrapped around the semiconductor layer by forming the source and drain regions adjacent to the gate structure on a first side of the semiconductor layer and in the undercuts on a second side of the semiconductor layer opposite the first side.

Abstract: A nanowire transistor structure is fabricated by using auxiliary epitaxial nucleation source/drain fin structures. The fin structures include semiconductor layers integral with nanowires that extend between the fin structures. Gate structures are formed between the fin structures such that the nanowires extend through the gate conductors. Following spacer formation and nanowire chop, source/drain regions are grown epitaxially between the gate structures.

Abstract: It is an object to provide a transistor having a new multigate structure in which operating characteristics and reliability are improved. In a transistor having a multigate structure, which includes two gate electrodes electrically connected to each other and a semiconductor layer including two channel regions connected in series formed between a source region and a drain region, and a high concentration impurity region is formed between the two channel regions; the channel length of the channel region adjacent to the source region is longer than the channel length of the channel region adjacent to the drain region.

Abstract: A thin film transistor, a manufacturing method thereof, an array substrate and a display apparatus are disclosed. The manufacturing method includes forming a gate electrode (2), a gate insulating layer (3), an active region (4), a source electrode (5) and a drain electrode (6) on a base substrate (1) with the active region being formed of ZnON material, and implanting the active region (4) with nitrogen ion while it being formed, so as to make the sub-threshold swing amplitude of the thin film transistor less than or equal to 0.5 mV/dec. The manufacturing method reduces the sub-threshold swing amplitude of the thin film transistor and improves the semiconductor characteristics of the thin film transistor.

Abstract: A semiconductor device of stable electrical characteristics, whose oxygen vacancies in a metal oxide is reduced, is provided. The semiconductor device includes a gate electrode, a gate insulating film over the gate electrode, a first metal oxide film over the gate insulating film, a source electrode and a drain electrode which are in contact with the first metal oxide film, and a passivation film over the source electrode and the drain electrode. A first insulating film, a second metal oxide film, and a second insulating film are stacked sequentially in the passivation film.

Abstract: This disclosure discloses an oxide semiconductor thin film, a thin film transistor, a manufacturing method and a device, belonging to the field of flat panel display. The oxide semiconductor thin film is made of an oxide containing zirconium and indium. A method of manufacturing the oxide semiconductor thin film comprises preparing a target using the oxide containing zirconium and indium, and sputtering the target to obtain the oxide semiconductor thin film.

Abstract: A semiconductor element having high mobility, which includes an oxide semiconductor layer having crystallinity, is provided. The oxide semiconductor layer includes a stacked-layer structure of a first oxide semiconductor film and a second oxide semiconductor film having a wider band gap than the first oxide semiconductor film, which is in contact with the first oxide semiconductor film. Thus, a channel region is formed in part of the first oxide semiconductor film (that is, in an oxide semiconductor film having a smaller band gap) which is in the vicinity of an interface with the second oxide semiconductor film. Further, dangling bonds in the first oxide semiconductor film and the second oxide semiconductor film are bonded to each other at the interface therebetween. Accordingly, a decrease in mobility resulting from an electron trap or the like due to dangling bonds can be reduced in the channel region.

Abstract: A semiconductor device includes a first barrier layer having a barrier property against oxygen and hydrogen over a substrate, a first insulator over the first barrier layer, a second insulator over the first insulator, a third insulator over the second insulator, a transistor including an oxide semiconductor over the third insulator, a fourth insulator including an oxygen-excess region over the transistor, and a second barrier layer having a barrier property against oxygen and hydrogen over the fourth insulator. The transistor includes a first conductor with oxidation resistance, a second conductor with oxidation resistance, and a third conductor with oxidation resistance, the second insulator includes a high-k material, the first barrier layer and the second barrier layer are in contact with each other in an outer edge of a region where the transistor is provided, and the transistor is surrounded by the first barrier layer and the second barrier layer.

Abstract: A TFT, a method for manufacturing the TFT, and an array substrate are disclosed. In the TFT according to the present disclosure, the nano conductive points that are independent from one another are formed in a channel area of the active layer, so that the channel area of the active layer can be divided into a plurality of sub channels that are independent from one another, and an equivalent electric field strength thereof can be increased. The larger the equivalent electric field strength is, the higher the carrier mobility ratio would be, and the larger the saturation current of the TFT would become. Therefore, the TFT with a higher definition and a higher aperture ratio can be manufactured.

Abstract: A miniaturized transistor is provided. A first layer is formed over a third insulator over a semiconductor; a second layer is formed over the first layer; an etching mask is formed over the second layer; the second layer is etched using the etching mask until the first layer is exposed to form a third layer; a selective growth layer is formed on a top surface and a side surface of the third layer; the first layer is etched using the third layer and the selective growth layer until the third insulator is exposed to form a fourth layer; and the third insulator is etched using the third layer, the selective growth layer, and the fourth layer until the semiconductor is exposed to form a first insulator.