Abstract: This invention discloses a semiconductor power device disposed in a semiconductor substrate comprising a lightly doped layer formed on a heavily doped layer and having an active cell area and an edge termination area. The edge termination area comprises a plurality P-channel MOSFETs. By connecting the gate to the drain electrode, the P-channel MOSFET transistors formed on the edge termination are sequentially turned on when the applied voltage is equal to or greater than the threshold voltage Vt of the P-channel MOSFET transistors, thereby optimizing the voltage blocked by each region.

Abstract: A method of dividing drain select gate electrodes in a three-dimensional vertical memory device is provided. An alternating stack of insulating layers and spacer material layers is formed over a substrate. A first insulating cap layer is formed over the alternating stack. A plurality of memory stack structures is formed through the alternating stack and the first insulating cap layer. The first insulating cap layer is vertically recessed, and a conformal material layer is formed over protruding portions of the memory stack structures. Spacer portions are formed by an anisotropic etch of the conformal material layer such that the sidewalls of the spacer portions having protruding portions. A self-aligned separator trench with non-uniform sidewalls having protruding portions is formed through an upper portion of the alternating stack by etching the upper portions of the alternating stack between the spacer portions.

Abstract: A semiconductor device having a high and stable operating voltage and a method of manufacturing the same, the semiconductor device including: a substrate having an active region including a channel region; a gate insulating layer that covers a top surface of the active region; a gate electrode that covers the gate insulating layer on the top surface of the active region; buried insulating patterns in the channel region of the active region at a lower side of the gate electrode and spaced apart from a top surface of the substrate; and a pair of source/drain regions in the substrate at both sides of each of the buried insulating patterns and extending from the top surface of the substrate to a level lower than that of each of the buried insulating patterns.

Abstract: A metal-oxide-semiconductor field-effect transistor (MOSFET) with integrated passive structures and methods of manufacturing the same is disclosed. The method includes forming a stacked structure in an active region and at least one shallow trench isolation (STI) structure adjacent to the stacked structure. The method further includes forming a semiconductor layer directly in contact with the at least one STI structure and the stacked structure. The method further includes patterning the semiconductor layer and the stacked structure to form an active device in the active region and a passive structure of the semiconductor layer directly on the at least one STI structure.

Abstract: A high voltage device includes a substrate, a first LDMOS transistor and a second LDMOS transistor disposed on the substrate. The first LDMOS transistor includes a first gate electrode disposed on the substrate. A first STI is embedded in the substrate and disposed at an edge of the first gate electrode and two first doping regions respectively disposed at one side of the first STI and one side of the first gate electrode. The second LDMOS transistor includes a second gate electrode disposed on the substrate. A second STI is embedded in the substrate and disposed at an edge of the second gate electrode. Two second doping regions are respectively disposed at one side of the second STI and one side of the second gate electrode, wherein the second STI is deeper than the first STI.

Abstract: Field effect transistors and methods of forming the same include forming a stack of nanowires of alternating layers of channel material and sacrificial material. A layer of sacrificial material forms a top layer of the stack. A dummy gate is formed over the stack. Stack material outside of a region covered by the dummy gate is removed. The sacrificial material is etched to form recesses in the sacrificial material layers. Spacers are formed in the recesses in the sacrificial material layers. At least one pair of spacers is formed in recesses above an uppermost layer of channel material. The dummy gates are etched away. The top layer of sacrificial material protects an uppermost layer of channel material from damage from the anisotropic etch. The sacrificial material is etched away to expose the layers of channel material. A gate stack is formed over, around, and between the layers of channel material.

Abstract: Disclosed is a method of manufacturing a junctionless transistor based on vertically integrated gate-all-around multiple nanowire channels including forming vertically integrated multiple nanowire channels in which a plurality of nanowires is vertically integrated, forming an interlayer dielectric layer (ILD) on the vertically integrated multiple nanowire channels, forming a hole in the interlayer dielectric layer such that at least some of the vertically integrated multiple nanowire channels is exposed, and forming a gate dielectric layer on the interlayer dielectric layer to fill the hole, wherein the forming of the gate dielectric layer on the interlayer dielectric layer to fill the hole includes depositing the gate dielectric layer on the interlayer dielectric layer to surround at least some of the vertically integrated multiple nanowire channels which is exposed though the hole.

Abstract: In one example, a method for fabricating a semiconductor device includes forming a mandrel comprising silicon. Sidewalls of the silicon are orientated normal to the <111> direction of the silicon. A nanowire is grown directly on at least one of the sidewalls of the silicon and is formed from a material selected from Groups III-V. Only one end of the nanowire directly contacts the silicon.

Abstract: This invention discloses a semiconductor power device disposed in a semiconductor substrate. The semiconductor power device comprises a plurality of trenches formed at a top portion of the semiconductor substrate extending laterally across the semiconductor substrate along a longitudinal direction each having a nonlinear portion comprising a sidewall perpendicular to a longitudinal direction of the trench and extends vertically downward from a top surface to a trench bottom surface. The semiconductor power device further includes a trench bottom dopant region disposed below the trench bottom surface and a sidewall dopant region disposed along the perpendicular sidewall wherein the sidewall dopant region extends vertically downward along the perpendicular sidewall of the trench to reach the trench bottom dopant region and pick-up the trench bottom dopant region to the top surface of the semiconductor substrate.

Abstract: A method of making a bipolar transistor includes patterning a first photoresist over a collector region of the bipolar transistor, the first photoresist defining a first opening. The method further includes performing a first implantation process through the first opening. The method further includes patterning a second photoresist over the collector region, the second photoresist defining a second opening different from the first opening. The method further includes performing a second implantation process through the second opening, wherein a dopant concentration resulting from the second implantation process is different from a dopant concentration resulting from the first implantation process.

Abstract: Provided is a method for manufacturing a thin SiC wafer by which a SiC wafer is thinned using a method without generating crack or the like, the method in which polishing after adjusting the thickness of the SiC wafer can be omitted. The method for manufacturing the thin SiC wafer 40 includes a thinning step. In the thinning step, the thickness of the SiC wafer 40 can be decreased to 100 ?m or less by performing the Si vapor pressure etching in which the surface of the SiC wafer 40 is etched by heating the SiC wafer 40 after cutting out of an ingot 4 under Si vapor pressure.

Abstract: Provided is a semiconductor wafer in which a nitride crystal layer on a silicon wafer includes a reaction suppressing layer to suppress reaction between a silicon atom and a Group-III atom, a stress generating layer to generate compressive stress and an active layer in which an electronic element is to be formed, the reaction suppressing layer, the stress generating layer and the active layer are arranged in an order of the reaction suppressing layer, the stress generating layer and the active layer with the reaction suppressing layer being positioned the closest to the silicon wafer, and the stress generating layer includes a first crystal layer having a bulk crystal lattice constant of al and a second crystal layer in contact with a surface of the first crystal layer that faces the active layer, where the second crystal layer has a bulk crystal lattice constant of a2 (a1<a2).

Abstract: A semiconductor device which can reduce power consumption and a method for manufacturing the same are provided. A semiconductor device comprises an Si (silicon) substrate, an SIC (silicon carbide) layer formed on the surface of the Si substrate, an AIN (aluminum nitride) layer formed on the surface of the SiC layer, an n-type GaN (gallium nitride) layer formed on the surface of the AIN layer, a first electrode formed at the surface side of the GaN layer, and a second electrode formed at the reverse face side of the Si substrate 1. The magnitude of electrical current which flows between the first electrode and the second electrode depends on electrical voltage between the first electrode and the second electrode.

Abstract: Provided is a semiconductor device having an RC-IGBT structure, the semiconductor device comprising an FWD (Free Wheel Diode) region and an IGBT (Insulated Gate Bipolar Transistor) region. Provided is a semiconductor device comprising: a semiconductor substrate; a transistor section formed on the semiconductor substrate; a diode section formed on the semiconductor substrate and including a lifetime killer at a front surface side of the semiconductor substrate; a gate runner provided between the transistor section and the diode section and electrically connected to a gate of the transistor section.

Abstract: A high electron mobility transistor includes a substrate including a first surface and a second surface facing each other and having a via hole passing through the first surface and the second surface, an active layer on the first surface, a cap layer on the active layer and including a gate recess region exposing a portion of the active layer, a source electrode and a drain electrode on one of the cap layer and the active layer, an insulating layer on the source electrode and the drain electrode and having on opening corresponding to the gate recess region to expose the gate recess region, a first field electrode on the insulating layer, a gate electrode electrically connected to the first field electrode on the insulating layer, and a second field electrode on the second surface and contacting the active layer through the via hole.

Abstract: A method of manufacturing a power metal oxide semiconductor field effect transistor includes: forming a field electrode in a field plate trench in a main surface of a semiconductor substrate; forming a gate trench in the main surface, the gate trench extending in a first direction parallel to the main surface; and for a gate electrode in the gate trench, the gate electrode being made of a gate electrode material that comprises a metal. The field plate trench is formed to have an extension length in the first direction which is less than double of an extension length of the field plate trench in a second direction, the second direction being perpendicular to the first direction.

Abstract: A semiconductor device includes a first type region including a first conductivity type. The semiconductor device includes a second type region including a second conductivity type. The semiconductor device includes a channel region extending between the first type region and the second type region. The semiconductor device includes a first silicide region on a first type surface region of the first type region. The first silicide region is separated at least one of a first distance from a first type diffusion region of the first type region or a second distance from the channel region.

Abstract: A spatial terahertz wave phase modulator based on the high electron mobility transistor is provided. The phase modulator combines the quick-response high electron mobility transistor with a novel metamaterial resonant structure, so as to rapidly modulate terahertz wave phases in a free space. The phase modulator includes a semiconductor substrate, an HEMT epitaxial layer, a periodical metamaterial resonant structure and a muff-coupling circuit. A concentration of 2-dimensional electron gas in the HEMT epitaxial layer is controlled through loading voltage signals, so as to change an electromagnetic resonation mode of the metamaterial resonant structure, thereby achieving phase modulation of terahertz waves. The phase modulator has a phase modulation depth of over 90 degrees within a large bandwidth, and a maximum phase modulation depth is about 140 degrees. Furthermore, the phase modulator is simple in structure, easy to machine, high in modulation speed, convenient to use, and easy to package.

Abstract: A method of processing a semiconductor device includes: creating first and second recesses in a surface of a semiconductor body; creating an insulation layer that forms first and second wells each having a common lateral extension range with the portion of the insulation layer located between the recesses; filling the wells with a plug material having the respective common lateral extension range with the insulation layer; removing a middle portion of the insulation layer located between the recesses; filling, with a filling material, a third recess created in a region where the middle portion has been removed and at least a portion of the space located between the wells; creating a first common surface of the insulation layer, the plug material, and the filling material; removing the plug material from the second well; and creating a second insulation layer that covers a side wall of the second recess.

Abstract: A silicon carbide semiconductor device, including a silicon carbide semiconductor structure, an insulated gate structure, an interlayer insulating film formed on the insulated gate structure, a poly-silicon film formed on the interlayer insulating film, and a main electrode formed on the poly-silicon film and in electrical connection with the silicon carbide semiconductor structure. The insulated gate structure includes a gate insulating film, which is a silicon dioxide film contacting the silicon carbide semiconductor structure, and a gate electrode formed on the gate insulating film.

Abstract: In an embodiment, a wide bandgap semiconductor power device, includes a wide bandgap semiconductor substrate layer; an epitaxial semiconductor layer disposed above the wide bandgap semiconductor substrate layer; a gate dielectric layer disposed directly over a portion of the epitaxial semiconductor layer; and a gate electrode disposed directly over the gate dielectric layer. The gate electrode includes an in-situ doped semiconductor layer disposed directly over the gate dielectric layer and a metal-containing layer disposed directly over the in-situ doped semiconductor layer.

Abstract: A semiconductor device of the present invention includes a semiconductor layer including a main IGBT cell and a sense IGBT cell connected in parallel to each other, a first resistance portion having a first resistance value formed using a gate wiring portion of the sense IGBT cell and a second resistance portion having a second resistance value higher than the first resistance value, a gate wiring electrically connected through mutually different channels to the first resistance portion and the second resistance portion, a first diode provided between the gate wiring and the first resistance portion, a second diode provided between the gate wiring and the second resistance portion in a manner oriented reversely to the first diode, an emitter electrode disposed on the semiconductor layer, electrically connected to an emitter of the main IGBT cell, and a sense emitter electrode disposed on the semiconductor layer, electrically connected to an emitter of the sense IGBT cell.

Abstract: One aspect of the disclosure provides for a method of forming a replacement gate structure. The method may include: removing a dummy gate from over a set of fins to form an opening in a dielectric layer exposing the set of fins, each fin in the set of fins being substantially separated from an adjacent fin in the set of fins via an dielectric; forming a protective cap layer within the opening over the exposed set of fins; removing a portion of the dielectric on each side of each fin in the set of fins; undercutting each fin by removing a portion of each fin in the set of fins to create a notch disposed under the protective cap layer; substantially filling each notch with an oxide; forming a gate dielectric over each fin in the set of fins; and forming a gate conductor over the gate dielectric, thereby forming the replacement gate structure.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: A method for fabricating an electronic device is provided to include: forming a hard mask pattern over a substrate to expose a gate formation region; forming a gate trench by etching the substrate using the hard mask pattern; forming a gate insulating layer over an inner wall of the gate trench; forming a gate electrode filling a lower portion of the gate trench in which the gate insulating layer is formed; forming an insulating material covering a resultant structure in which the gate electrode is formed; forming a gate protective layer having a top surface lower than a bottom surface of the hard mask pattern; removing the hard mask pattern; recessing the substrate so that a top surface of the substrate is lower than the top surface of the gate protective layer; and forming a conductive pattern filling a space formed by the recessing of the substrate.

Abstract: A method for producing a semiconductor device includes forming a semiconductor-pillar on a substrate and forming a laminated-structure of at least two composite layers, each including a metal layer and a semiconductor layer in contact with the metal layer, the semiconductor layer containing donor or acceptor atoms, and two interlayer insulating layers sandwiching the composite layers, such that a side surface of at least one of the two interlayer insulating layers is separated from a side surface of the semiconductor pillar. The laminated-structure surrounds the semiconductor pillar. A first heat treatment causes a reaction between the metal layer and the semiconductor layer to form an alloy layer, and brings the alloy layer into contact with the side surface of the semiconductor pillar. A second heat treatment to expands the alloy layer into the semiconductor pillar and diffuses dopant atoms into the semiconductor pillar to form an impurity region therein.

Abstract: A semiconductor device includes a fin structure which vertically protrudes from a substrate and extends in a first direction parallel to a top surface of the substrate. The fin structure includes a lower pattern and an active pattern vertically protruding from a top surface of the lower pattern. The top surface of the lower pattern includes a flat portion substantially parallel to the top surface of the substrate. The lower pattern includes a first sidewall extending in the first direction and a second sidewall extending in a second direction crossing the first direction. The first sidewall is inclined relative to the top surface of the substrate at a first angle greater than a second angle corresponding to the second sidewall that is inclined relative to the top surface of the substrate.

Abstract: The semiconductor device is manufactured through the following steps: after first heat treatment is performed on an oxide semiconductor film, the oxide semiconductor film is processed to form an oxide semiconductor layer; immediately after that, side walls of the oxide semiconductor layer are covered with an insulating oxide; and in second heat treatment, the side surfaces of the oxide semiconductor layer are prevented from being exposed to a vacuum and defects (oxygen deficiency) in the oxide semiconductor layer are reduced.

Abstract: A bipolar transistor is supported by a single-crystal silicon substrate including a collector contact region. A first epitaxial region forms a collector region of a first conductivity type on the collector contact region. A second epitaxial region forms a base region of a second conductivity type. Deposited semiconductor material forms an emitter region of the first conductivity type. The collector region, base region and emitter region are located within an opening having sidewalls lined with an insulating sheath. A portion of the insulating sheath adjacent the base region is removed and a base contact region is formed by epitaxial material grown from a portion of the base region exposed by removal of the portion of the insulating sheath.

Abstract: A bipolar junction transistor includes an intrinsic base formed on a substrate. The intrinsic base includes a superlattice stack including a plurality of alternating layers of semiconductor material. A collector and emitter are formed adjacent to the intrinsic base on opposite sides of the base. An extrinsic base structure is formed on the intrinsic base.

Abstract: The present disclosure relates to a semiconductor device with multiple heterojunction bipolar transistors (HBTs) that have different emitter ballast resistances. The disclosed semiconductor device includes a substrate, a first HBT and a second HBT formed over the substrate. The first HBT includes a first collector, a first base over the first collector, a first emitter over the first base, and a first cap structure over the first emitter. The second HBT includes a second collector, a second base over the second collector, a second emitter over the second base, and a second cap structure over the second emitter. Herein, the first cap structure is different from the second cap structure, such that a first emitter ballast resistance from the first cap structure is at least 1.5 times greater than a second emitter ballast resistance from the second cap structure.

Abstract: Provided is a semiconductor device comprising: a semiconductor substrate; a plurality of gate trench sections formed in the semiconductor substrate; and a plurality of emitter trench sections formed in the semiconductor substrate, one or more emitter trench sections provided in each region between adjacent gate trench sections of the plurality of gate trench sections, wherein the semiconductor device includes at least one of: pairs of gate trench sections in which at least two gate trench sections of the plurality of gate trench sections are connected; and a pair of emitter trench sections in which at least two emitter trench sections of the plurality of emitter trench sections are connected.

Abstract: A semiconductor device, including a first groove, a second groove and a first impurity region provided on a semiconductor substrate, a second impurity region provided in the first impurity region, a gate electrode provided in the first groove, a first insulating film provided between the first groove and the gate electrode, a second insulating film provided in the second groove, and a third insulating film provided astride tops of the first groove and the second groove. Each of the first and second insulating films has a lower half portion that is thicker than an upper half portion thereof. The lower half portions of the first and second insulating films are connected. The gate electrode has first and second portions thereof respectively contacting the lower and upper half portions of the first insulating film, a width of the first portion being narrower than a width of the second portion.

Abstract: Transistors or transistor layers include an InAlN and AlGaN bi-layer capping stack on a 2DEG GaN channel, such as for GaN MOS structures on Si substrates. The GaN channel may be formed in a GaN buffer layer or stack, to compensate for the high crystal structure lattice size and coefficient of thermal expansion mismatch between GaN and Si. The bi-layer capping stack an upper InAlN layer on a lower AlGaN layer to induce charge polarization in the channel, compensate for poor composition uniformity (e.g., of Al), and compensate for rough surface morphology of the bottom surface of the InAlN material. It may lead to a sheet resistance between 250 and 350 ohms/sqr. It may also reduce bowing of the GaN on Si wafers during growth of the layer of InAlN material, and provide a AlGaN setback layer for etching the InAlN layer in the gate region.

Abstract: A semiconductor device includes a semiconductor substrate configured to include a channel, a gate supported by the semiconductor substrate to control current flow through the channel, a first dielectric layer supported by the semiconductor substrate and including an opening in which the gate is disposed, and a second dielectric layer disposed between the first dielectric layer and a surface of the semiconductor substrate in a first area over the channel. The second dielectric layer is patterned such that the first dielectric layer is disposed on the surface of the semiconductor substrate in a second area over the channel.

Abstract: The present invention provides a vertical double-diffused metal-oxide semiconductor field-effect transistor and a manufacturing method. The manufacturing method comprises: providing a substrate of a first conductive type; growing a first epitaxial layer of the first conductive type above the substrate; forming column regions of the first conductive type and column regions of a second conductive type spaced in a staggered manner above the first epitaxial layer; forming a third epitaxial layer of the first conductive type above the column regions of the first conductive type, and forming a well region of the second conductive type above the column regions of the second conductive type; forming a gate region on a surface of the third epitaxial layer; forming a source region of the first conductive type in the well region of the second conductive type; and forming a gate metal layer, a source metal layer, and a drain metal layer.

Abstract: A semiconductor device includes a transistor in a semiconductor substrate having a first main surface. The transistor includes a source region, a source contact, the source contact including a first and second source contact portion, and a gate electrode in a gate trench in the first main surface adjacent to a body region. The body region and a drift zone are disposed along a first direction parallel to the first main surface between the source region and a drain region. The second source contact portion is disposed at a second main surface of the semiconductor substrate. The first source contact portion includes a source conductive material in direct contact with the source region, the first source contact portion further including a portion of the semiconductor substrate between the source conductive material and the second source contact portion. The semiconductor device further includes a temperature sensor in the semiconductor substrate.

Abstract: A method for manufacturing a fin field-effect transistor (FinFET) device, comprises patterning a first layer on a substrate to form at least one fin, patterning a second layer under the first layer to remove a portion of the second layer on sides of the at least one fin, forming a sacrificial gate electrode on the at least one fin, and a spacer on the sacrificial gate electrode, selectively removing the sacrificial gate electrode, depositing an oxide layer on top and side portions of the at least one fin corresponding to a channel region of the at least one fin, performing thermal oxidation to condense the at least one fin in the channel region until a bottom portion of the at least one fin is undercut, and stripping a resultant oxide layer from the thermal oxidation, leaving a gap in the channel region between a bottom portion of the at least one fin and the second layer.

Abstract: A semiconductor device includes a substrate, a plurality of fins on the substrate, wherein the plurality of fins each include a fin channel region, first isolation regions on the substrate corresponding to active gate regions, a second isolation region on the substrate corresponding to a dummy gate region, wherein a height of the second isolation region is greater than a height of the first isolation regions, a plurality of active gate structures formed around the fins, and on the first isolation regions, and a dummy gate structure formed on the second isolation region.

Abstract: Apparatus and associate methods relate to a high-voltage MOSFET bounded by two trenches, each having dielectric sidewalls and a dielectric bottom isolating a top field plate and a bottom field plate. The top field plate is electrically connected to a biasing circuit net, and the bottom field plate is biased via a capacitive coupling to the top field plate. The upper field plate and lower field plate are configured to deplete the majority carriers in a drain region of the MOSFET bounded by the two trenches so as to equalize two local maxima of an electric field induced by a drain/body bias, the two local maxima located proximate a drain/body metallurgical junction and proximate a trench bottom. The two local maxima of the electric field are equalized by controlling a depth location of an intervening dielectric between the upper field plate and the lower field plate.

Abstract: A semiconductor device capable of increasing a value of current that flows through the whole chip until a p-n diode in a unit cell close to a termination operates and reducing a size of the chip and a cost of the chip resulting from the reduced size, and including a second well region formed on both sides, as seen in plan view, of the entirety of a plurality of first well regions, a second ohmic electrode located over the second well region, a third separation region of a first conductivity type that is positioned closer to the first well regions than the second ohmic electrode in the second well region and that is formed to penetrate the second well region from a surface layer of the second well region in a depth direction, and a second Schottky electrode located on the third separation region.

Abstract: Techniques are disclosed for forming a GaN transistor on a semiconductor substrate. An insulating layer forms on top of a semiconductor substrate. A trench, filled with a trench material comprising a III-V semiconductor material, forms through the insulating layer and extends into the semiconductor substrate. A channel structure, containing III-V material having a defect density lower than the trench material, forms directly on top of the insulating layer and adjacent to the trench. A source and drain form on opposite sides of the channel structure, and a gate forms on the channel structure. The semiconductor substrate forms a plane upon which both GaN transistors and other transistors can form.

Abstract: A method for manufacturing a semiconductor device comprises epitaxially growing a plurality of silicon layers and compressively strained silicon germanium (SiGe) layers on a substrate in a stacked configuration, wherein the silicon layers and compressively strained SiGe layers are alternately stacked on each other starting with a silicon layer on a bottom of the stacked configuration, patterning the stacked configuration to a first width, selectively removing a portion of each of the silicon layers in the stacked configuration to reduce the silicon layers to a second width less than the first width, forming an oxide layer on the compressively strained SiGe layers of the stacked configuration, wherein forming the oxide layer comprises fully oxidizing the silicon layers so that portions of the oxide layer are formed in place of each fully oxidized silicon layer, and removing part of the oxide layer while maintaining at least part of the portions of the oxide layer formed in place of each fully oxidized silicon

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a fin structure over a semiconductor substrate and a gate stack covering a portion of the fin structure. The gate stack includes a gate dielectric layer, a work function layer, and a conductive filling over the work function layer. The semiconductor device structure also includes a dielectric layer covering the fin structure. The dielectric layer is in direct contact with the conductive filling.

Abstract: The present application discloses a thin film transistor including an active layer, and a source electrode and a drain electrode on the active layer; each of the source electrode and the drain electrode includes a metal electrode sub-layer, and a diffusion barrier sub-layer made of a material comprising M1OaNb, wherein M1 is a single metal or a combination of metals, a?0, and b>0, between the metal electrode sub-layer and the active layer for preventing diffusion of metal electrode material into the active layer.

Abstract: To provide a semiconductor device that includes an oxide semiconductor and is miniaturized while keeping good electrical properties. In the semiconductor device, an oxide semiconductor layer is surrounded by an insulating layer including an aluminum oxide film containing excess oxygen. Excess oxygen in the aluminum oxide film is supplied to the oxide semiconductor layer including a channel by heat treatment in a manufacturing process of the semiconductor device. Furthermore, the aluminum oxide film forms a barrier against oxygen and hydrogen. It is thus possible to suppress the removal of oxygen from the oxide semiconductor layer surrounded by the insulating layer including an aluminum oxide film, and the entry of impurities such as hydrogen into the oxide semiconductor layer; as a result, the oxide semiconductor layer can be made highly intrinsic. In addition, gate electrode layers over and under the oxide semiconductor layer control the threshold voltage effectively.

Abstract: A semiconductor device is manufactured using a transistor in which an oxide semiconductor is included in a channel region and variation in electric characteristics due to a short-channel effect is less likely to be caused. The semiconductor device includes an oxide semiconductor film having a pair of oxynitride semiconductor regions including nitrogen and an oxide semiconductor region sandwiched between the pair of oxynitride semiconductor regions, a gate insulating film, and a gate electrode provided over the oxide semiconductor region with the gate insulating film positioned therebetween. Here, the pair of oxynitride semiconductor regions serves as a source region and a drain region of the transistor, and the oxide semiconductor region serves as the channel region of the transistor.

Abstract: To offer a semiconductor device including a thin film transistor having excellent characteristics and high reliability and a method for manufacturing the semiconductor device without variation. The summary is to include an inverted-staggered (bottom-gate structure) thin film transistor in which an oxide semiconductor film containing In, Ga, and Zn is used for a semiconductor layer and a buffer layer is provided between the semiconductor layer and source and drain electrode layers. An ohmic contact is formed by intentionally providing a buffer layer containing In, Ga, and Zn and having a higher carrier concentration than the semiconductor layer between the semiconductor layer and the source and drain electrode layers.

Abstract: A nanowire device includes a first component formed on a substrate and a second component disposed apart from the first component on the substrate. A nanowire is configured to connect the first component to the second component. An anchor pad is formed along a span of the nanowire and configured to support the nanowire along the span to prevent sagging.