Abstract: Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A nanosheet stack of alternating nanosheets of a sacrificial semiconductor material nanosheet and a semiconductor channel material nanosheet and a dielectric nanosheet as a top layer of the nanosheet stack is provided above a semiconductor substrate. A dummy gate with a gate cap and spacers on the sidewalls straddle over the nanosheet stack. End portions of the sacrificial semiconductor material nanosheets are recessed. A dielectric spacer material layer is formed. A source/drain region is formed on the sidewalls of each semiconductor channel material nanosheet. The dummy gate and gate cap are removed. Each sacrificial semiconductor material nanosheet is removed. A functional gate structure is formed that wraps around each suspended semiconductor channel material nanosheet. A self-aligned source/drain contact region is formed.

Abstract: In some implementations, a buffer layer is formed under a source/drain region of a device. A shape of the buffer layer may include a curved top surface having a height that extends to increase coverage of nanosheets of a fin structure of the device. The shape also includes regions having widths that extend towards shallow trench isolation regions of the device. The shape reduces a likelihood of dopants diffusing from the source/drain region into a mesa region of the fin structure. As a result, a performance of the device may be increased by decreasing short channel effects, decreasing an off-current of the device, and decreasing leakage within the device, among other examples.

Abstract: A semiconductor device including a nanodevice located on a substrate, where the nanodevice includes a plurality of nanosheets. Each of the plurality of nanosheets are spaced apart from each other by a first distance. A gate located on the substrate, where the gate surrounds each of the plurality of nanosheets. A first dielectric layer located on the substrate, where the first dielectric layer is located adjacent to a sidewall of the gate. The gate has a first thickness when measured from the sidewall of one of the plurality of nanosheets to a sidewall of the first dielectric layer, where the first thickness is larger than the first distance. An inner spacer located on the substrate, where the inner spacer is wraps around an end of each of the plurality of nanosheets. The inner spacer has a second thickness, where the second thickness is substantially equal to the first distance.

Abstract: A method for forming a semiconductor device structure includes forming first nanostructures and second nanostructures over a substrate. The method also includes forming a first metal gate layer surrounding the first nanostructures and over the first nanostructures and the second nanostructures. The method also includes etching back the first metal gate layer over the first nanostructures and the second nanostructures. The method also includes removing the first metal gate layer over the second nanostructures. The method also includes forming a second metal gate layer surrounding the second nanostructures and over the first nanostructures and the second nanostructures.

Abstract: Integrated circuit structures having backside self-aligned conductive source or drain contacts, and methods of fabricating integrated circuit structures having backside self-aligned conductive source or drain contacts, are described. For example, an integrated circuit structure includes a sub-fin structure over a vertical stack of horizontal nanowires. An epitaxial source or drain structure is laterally adjacent and coupled to the vertical stack of horizontal nanowires. A conductive source or drain contact is laterally adjacent to the sub-fin structure and is on and in contact with the epitaxial source or drain structure. The conductive source or drain contact does not extend around the epitaxial source or drain structure.

Abstract: A semiconductor device cell includes a drift region having a first conductivity type, a well region having a second conductivity type disposed adjacent to the drift region, the well region defining a set of well region segments. A source region having the first conductivity type is disposed adjacent to the well region and surrounded by the well region. A channel region having the second conductivity type, and defining a set of channel region segments a periphery of the channel region segment being surrounded by the well region. The well region, source region, and channel region cooperatively define a first axial length extending across the surface.

Abstract: A semiconductor device includes a transistor having macro cells. A plurality of the macro cells include a first macro cell and a second macro cell. Each first and second macro cell includes trenches formed in a first main surface of a semiconductor substrate. The trenches pattern the semiconductor substrate into mesas and include a conductive trench, with a conductive material in the conductive trench being electrically connected to a terminal. A majority of all trenches of the first macro cell exclusively run in a first direction. A majority of all trenches of the second macro cell exclusively run in a second direction different from the first direction. At least one first macro cell is arranged adjacent to at least one second macro cell.

Abstract: An insulated gate bipolar transistor (IGBT) is proposed. The IGBT includes a semiconductor body having a first surface and a second surface. The IGBT further includes an active area and an edge termination area that at least partly surrounds the active area. The active area includes a first part of an active IGBT area and a second part of the active IGBT area. The IGBT further includes a contact on the second surface of the semiconductor body. A minimum vertical distance between the contact in the first part of the active IGBT area and a reference level at the first surface is larger than a minimum vertical distance between the contact in the second part of the active IGBT area and the reference level at the first surface.

Abstract: Embodiments of the disclosure provide a bipolar transistor structure having a base with a varying horizontal width and methods to form the same. The bipolar transistor structure includes a first emitter/collector (E/C) layer on an insulator layer. A base layer is over the insulator layer. A spacer between the first E/C layer and the base layer. The base layer includes a lower base region, and the spacer is adjacent to the lower base region and the first E/C layer. An upper base region is on the lower base region and the spacer. A horizontal width of the upper base region is larger than a horizontal width of the lower base region.

Abstract: A semiconductor field-effect transistor, a power amplifier comprising the same and a manufacturing method thereof are provided herein. The semiconductor field-effect transistor contains an n-type doped layer arranged close to the edge of the two-dimensional electron gas area in a channel layer; said n-type doped layer is arranged to adjust the distribution of electron concentration in the transistor, and to improve the RF linearity of the overall component; thereby not only the threshold voltage can be controlled through the adjustment of the charge, but the contact and series resistance can also be reduced.

Abstract: The scaling of features in ICs has been a driving force behind an ever-growing semiconductor industry. As transistors of the ICs become smaller, their gate lengths become smaller, leading to undesirable short-channel effects such as poor leakage, poor subthreshold swing, drain-induced barrier lowering, etc. Reducing transistor dimensions at the gate allows keeping the footprint of the transistor relatively small and comparable to what could be achieved implementing a transistor with a shorter gate length while effectively increasing transistor's effective gate length and thus reducing the negative impacts of short-channel effects. This architecture may be optimized even further if transistors are to be operated at relatively low temperatures, e.g., below 200 Kelvin degrees or lower.

Abstract: Provided is a semiconductor device, including: a gate electrode having at least a part buried in a semiconductor layer; a deep p layer having at least a part buried in the semiconductor layer to a same depth as a buried lower end portion of the gate electrode or a position deeper than the buried lower end portion; and a channel layer, wherein: the deep p layer is formed by a crystalline oxide semiconductor; and a carrier concentration of the deep p layer is higher than a carrier concentration of the channel layer.

Abstract: A manufacturing method of a semiconductor device includes preparing a silicon carbide substrate, growing an epitaxial layer, and forming a structure. The silicon carbide substrate has an upper surface on which an alignment mark having a recessed shape is disposed, and a perpendicular line to the upper surface is inclined with respect to a [0001] direction toward a [11-20] direction. The epitaxial layer is grown on the upper surface and covers the alignment mark. The structure is formed on or above the upper surface at a position apart from the alignment mark by an interval P in the [11-20] direction along the upper surface. The interval P satisfies a relationship of D/tan ? < P < 10D/tan ?, where D is a depth of the alignment mark and ? is an inclination angle of the perpendicular line with respect to the [0001] direction.

Abstract: A semiconductor device is disclosed. The semiconductor device has a substrate with a gallium nitride layer (14) disposed over the substrate. A scandium aluminum nitride layer (10) is disposed over the gallium nitride layer. A source (18) is in contact with the gallium nitride layer, and a drain (20) is spaced from the source, wherein the drain is in contact with the gallium nitride layer.

Abstract: The present invention is a nitride semiconductor wafer, including: a silicon single-crystal substrate; and a device layer composed of a nitride semiconductor above the silicon single-crystal substrate, wherein the silicon single-crystal substrate is a CZ silicon single-crystal substrate, and has a resistivity of 1000 ?·cm or more, an oxygen concentration of 5.0×1016 atoms/cm3 (JEIDA) or more and 2.0×1.017 atoms/cm3 (JEIDA) or less, and a nitrogen concentration of 5.0×1014 atoms/cm3 or more. This provides a nitride semiconductor wafer that hardly causes plastic deformation even using a high-resistant low-oxygen silicon single-crystal substrate produced by the CZ method, which is suitably used for a high-frequency device, and that can reduce warpage of the substrate.

Abstract: A nitride semiconductor device includes a channel layer, a barrier layer made of AlxInyGa1-x-yN(x>0, x+y?1), an active region that has a layered structure including the channel layer and the barrier layer, an inactive region that is formed at the layered structure around the active region and that is a concave portion having a bottom portion that reaches the channel layer, a gate layer made of a nitride semiconductor selectively formed on the barrier layer in the active region, a gate electrode formed on the gate layer, a first insulating film that covers the gate electrode and that is in contact with the barrier layer in the active region, and a second insulating film that covers the first insulating film and that is in contact with the inactive region.

Abstract: A Group III-V compound semiconductor device includes a Group III-V compound substrate and a passivation structure. The passivation structure is disposed on a surface of the Group III-V compound substrate and includes a scandium-nitrogen-containing layer and a scandium-oxygen-containing layer sequentially stacked in that order in a direction away from the surface of the Group III-V compound substrate.

Abstract: A semiconductor device includes a substrate including an active region, a first gate line and a second gate line in the active region, a first source/drain contact pattern in the active region at one side of the first gate line, a second source/drain contact pattern in the active region at one side of the second gate line, and a dummy source/drain contact pattern in the active region between the first gate line and the second gate line. The first gate line and the second gate line may be spaced apart from each other in the first direction and may extend in the second direction. The second direction may cross the first direction. A size of the dummy source/drain contact pattern may be less than a size of the first source/drain contact pattern and a size of the second source/drain contact pattern.

Abstract: A high electron mobility transistor includes a substrate, a mesa structure disposed on the substrate, a passivation layer disposed on the mesa structure, and at least a contact structure disposed in the passivation layer and the mesa structure. The mesa structure includes a channel layer, a barrier layer on the channel layer, two opposite first edges extending along a first direction, and two opposite second edges extending along a second direction. The contact structure includes a body portion and a plurality of protruding portions. The body portion penetrates through the passivation layer. The protruding portions penetrate through the barrier layer and a portion of the channel layer. In a top view, the body portion overlaps the two opposite first edges of the mesa structure without overlapping the two opposite second edges of the mesa structure.

Abstract: The present disclosure describes a structure with front and back side power supply interconnects. The structure includes a transistor structure disposed in a substrate, where the transistor structure includes a source/drain (S/D) region. The structure also includes a front side power supply line above a top surface of the substrate, wherein the front side power supply line is electrically connected to a power supply metal line. The structure further includes a back side power supply line below a bottom surface of the substrate. A front side metal via electrically connects the front side power supply line to a front surface of the S/D region. A back side metal via electrically connects the back side power supply line to a back surface of the S/D region.

Abstract: Spacer self-aligned via structures for gate contact or trench contact are described. In an example, an integrated circuit structure includes a plurality of gate structures above a substrate. A plurality of conductive trench contact structures is alternating with the plurality of gate structures. A corresponding one of a plurality of dielectric spacers is between adjacent ones of the plurality of gate structures and the plurality of conductive trench contact structures. The plurality of dielectric spacers protrudes above the plurality of gate structures and above the plurality of conductive trench contact structures. A conductive structure is in direct contact with one of the plurality of gate structures or with one of the plurality of conductive trench contact structures. The conductive structure has a flat edge along a direction across the one of the plurality of gate structures or the one of the plurality of conductive trench contact structures.

Abstract: A method according to the present disclosure includes receiving a workpiece including a gate structure, a first source/drain (S/D) feature, a second S/D feature, a first dielectric layer over the gate structure, the first S/D feature, the second S/D feature, a first S/D contact over the first S/D feature, a second S/D contact over the second S/D feature, a first etch stop layer (ESL) over the first dielectric layer, and a second dielectric layer over the first ESL, forming a S/D contact via through the second dielectric layer and the first ESL to couple to the first S/D contact, forming a gate contact opening through the second dielectric layer, the first ESL, and the first dielectric layer to expose the gate structure, and forming a common rail opening adjoining the gate contact opening to expose the second S/D contact, and forming a common rail contact in the common rail opening.

Abstract: Contact over active gate (COAG) structures with uniform and conformal gate insulating cap layers, and methods of fabricating contact over active gate (COAG) structures using uniform and conformal gate insulating cap layers, are described. In an example, an integrated circuit structure includes a gate structure. An epitaxial source or drain structure is laterally spaced apart from the gate structure. A dielectric spacer is laterally between the gate structure and the epitaxial source or drain structure, the dielectric spacer having an uppermost surface below an uppermost surface of the gate structure. A gate insulating cap layer is on the uppermost surface of the gate structure and along upper portions of sides of the gate structure, the gate insulating cap layer distinct from the dielectric spacer.

Abstract: Integrated circuit structures having backside self-aligned penetrating conductive source or drain contacts, and methods of fabricating integrated circuit structures having backside self-aligned penetrating conductive source or drain contacts, are described. For example, an integrated circuit structure includes a sub-fin structure over a vertical stack of horizontal nanowires. An epitaxial source or drain structure is laterally adjacent and coupled to the vertical stack of horizontal nanowires. A conductive source or drain contact is laterally adjacent to the sub-fin structure and extends into the epitaxial source or drain structure. The conductive source or drain contact does not extend around the epitaxial source or drain structure.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a source/drain region arranged within a substrate. A select gate and a memory gate are arranged over the substrate. An inter-gate dielectric structure is arranged between the memory gate and the select gate. A conductive contact is disposed on the source/drain region and vertically extends from a bottom of the select gate to a top of the select gate. The select gate is closer to the conductive contact than the memory gate. The select gate has a first outermost sidewall that faces away from the memory gate and a second outermost sidewall that faces the memory gate. The first outermost sidewall is taller than the second outermost sidewall.

Abstract: An embodiment of the present invention provides a method of fabricating a semiconductor device capable of relieving a dangling bond. The semiconductor device comprises a device isolation layer defining a plurality of active regions in a substrate, the device isolation layer including a first region where the active regions are spaced apart from each other at a first interval along a first direction and a second region where the active regions are spaced apart from each other at a second interval along the first direction, the second interval being wider than the first interval; a gate trench extending in the first direction to cross the active regions and the device isolation layer; and a buried gate structure gap-filling the gate trench, wherein a portion of the device isolation layer includes an air gap acting as a hydrogen pocket in a lower portion.

Abstract: A semiconductor device includes: a semiconductor layer, a gate insulating layer, and a gate electrode sequentially formed in a trench formed to a predetermined depth from a first surface of a first substrate; a third substrate bonded to a second surface opposite to the first surface of the first substrate; and an air gap interposed between the semiconductor layer and the first substrate and between the semiconductor layer and the third substrate.

Abstract: A semiconductor device includes: a substrate including a gate trench; a gate dielectric layer formed along sidewalls and bottom surfaces of the gate trench; a high work function layer and a lower gate electrode that fill a bottom portion of the gate trench over the gate dielectric layer; an upper gate electrode including a low work function adjusting element over the lower gate electrode and including the same metal nitride as a material of the lower gate electrode; and a capping layer that gap-fills the other portion of the gate trench over the upper gate electrode.

Abstract: In a semiconductor device, a semiconductor substrate has an element region and a peripheral region, and trenches are defined on an upper surface of the semiconductor substrate. The trenches extend in a first direction, and are arranged at intervals in a second direction. The element region includes an n-type source region, a p-type contact region, a p-type body region, an n-type drift region, a p-type bottom region, and p-type connection regions. The bottom region is spaced from a bottom surface of the trenches. The connection regions connect the body region and the bottom region, extend in the first direction, and are arranged at intervals in the second direction. The element region has outer side portions and a central portion in the second direction. An interval between the connection regions in the second direction is greater in the outer side portion than in the central portion.

Abstract: According to one embodiment, a semiconductor device includes first and second electrodes, first to sixth semiconductor regions, a gate electrode, and a conductive part. The first semiconductor region is located on the first electrode. The first semiconductor region includes first and second regions. The second semiconductor region is located on the first region. The gate electrode is located on the second semiconductor region with a gate insulating layer interposed. The third semiconductor region is located on the first region and is separated from the second semiconductor region. The conductive part is located on the third semiconductor region with an insulating layer interposed. The fourth semiconductor region is located on the second region. The fifth semiconductor region is located on a portion of the fourth semiconductor region. The sixth semiconductor region contacts the third semiconductor region. The second electrode is located on the fourth and fifth semiconductor regions.

Abstract: Gate-all-around integrated circuit structures having additive gate structures are described. For example, an integrated circuit structure includes a first vertical arrangement of horizontal nanowires, and a second vertical arrangement of horizontal nanowires. A P-type gate stack is over the first vertical arrangement of horizontal nanowires, the P-type gate stack having a P-type conductive layer over a first gate dielectric, and an intervening conductive seed layer between the P-type conductive layer and the first gate dielectric. An N-type gate stack is over the second vertical arrangement of horizontal nanowires, the N-type gate stack having an N-type conductive layer over a second gate dielectric, and the intervening conductive seed layer between the N-type conductive layer and the second gate dielectric. The P-type gate stack is in contact with the N-type gate stack.

Abstract: Gate-all-around integrated circuit structures having common metal gates and having gate dielectrics with differentiated dipole layers are described. For example, an integrated circuit structure includes a first vertical arrangement of horizontal nanowires, and a second vertical arrangement of horizontal nanowires. A P-type gate stack is over the first vertical arrangement of horizontal nanowires, the P-type gate stack having a mid-gap to P-type conductive layer over a first gate dielectric including a high-k dielectric layer and a first dipole material layer. An N-type gate stack is over the second vertical arrangement of horizontal nanowires, the N-type gate stack having the mid-gap to P-type conductive layer over a second gate dielectric including the high-k dielectric layer and a second dipole material layer, the second dipole layer different than the first dipole material layer.

Abstract: A semiconductor device with doped shallow trench isolation (STI) structures and a method of fabricating the same are disclosed. The method includes forming a fin structure on a substrate, forming a superlattice structure with first and second nanostructured layers arranged in an alternating configuration on the fin structure, depositing an oxide liner surrounding the superlattice structure and the fin structure in a first deposition process, forming a dopant source liner on the oxide liner, depositing an oxide fill layer on the dopant source liner in a second deposition process different from the first deposition process, performing a doping process to form a doped oxide liner and a doped oxide fill layer, removing portions of the doped oxide liner, the doped oxide fill layer, and the dopant source liner from sidewalls of the superlattice structure, and forming a gate structure on the fin structure and surrounding the first nanostructured layers.

Abstract: A semiconductor device includes a semiconductor layer, a first insulating film provided on the semiconductor layer, a gate wiring provided on the first insulating film, and a source electrode provided on the first insulating film. The device further includes a second insulating film provided on the gate wiring and the source electrode and including a portion sandwiched between the gate wiring and the source electrode, and a drain electrode provided below the semiconductor layer. Further, an upper surface of the first insulating film includes a first region having a first concentration of phosphorus and a second region having a second concentration of phosphorus that is higher than the first concentration. The first region is present between the semiconductor layer and the gate wiring or the source electrode, and the second region is present between the semiconductor layer and the portion of the second insulating film.

Abstract: The invention discloses a transistor structure including a substrate, a semiconductor layer disposed on the substrate and a gate layer disposed on the semiconductor layer, wherein the gate layer includes at least one gate having a first height, a first side and a second side opposite to the first side, a first dielectric spacer is disposed at the first side of the at least one gate, a first air spacer having a second height is disposed inside the first dielectric spacer, and the second height is lower than the first height.

Abstract: A transistor and a fabrication method thereof are provided. The transistor includes a substrate, a low-dimensional material layer provided above the substrate, a gate, a source, a drain, a gate dielectric layer, and spacers. The source is located at a first side of the gate. The drain is located at a second side of the gate. The gate dielectric layer is provided between the gate and the low-dimensional material layer. The spacers are provided between the source and the gate and between the drain and the gate, respectively, in which dipoles are formed in the spacers to electrostatically dope the low-dimensional material layer. In the transistor, the dipoles in the spacers may be used to electrostatically dope the channel in the spacer region.

Abstract: According to one embodiment, a nitride semiconductor includes a nitride member. The nitride member includes a first nitride region including Alx1Ga1-×1N (0 < x1 ? 1), a second nitride region including Alx2Ga1-x2N (0 ? x2 < 1), and an intermediate region being between the first nitride region and the second nitride region. In a first direction from the first nitride region to the second nitride region, an oxygen concentration in the nitride member has a peak value at a first position included in the intermediate region. The peak value is 4.9 times or more a first oxygen concentration in the first nitride region. A second carbon concentration in the second nitride region is higher than a first carbon concentration in the first nitride region.

Abstract: A method for manufacturing a semiconductor device, includes forming source and drain electrodes on a semiconductor layer provided above a substrate; forming a first insulating film covering a surface of the semiconductor layer, between the source and drain electrodes, forming a second insulating film on the first insulating film, forming a mask on the second insulating film, the mask having an opening between the source and drain electrodes in a plan view viewed in a direction perpendicular to a substrate surface, forming a first gate opening in the first insulating film and forming a second gate opening in the second insulating film, by etching the first and second insulating films through the opening, and forming a gate electrode on the first and second insulating films, the gate electrode making a Schottky contact with the semiconductor layer through the first and second gate openings.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a plurality of first nanostructures stacked over a substrate in a vertical direction. The semiconductor device structure includes a first gate structure surrounding the first nanostructures. The semiconductor device structure also includes a first gate spacer layer formed adjacent to the first gate structure. A topmost first nanostructure has a first portion directly below the gate spacer layer and a second portion directly below the first gate structure, and the first portion has a first height along the vertical direction, the second portion has a second height along the vertical direction, and the first height is greater than the second height.

Abstract: A method used in forming a memory array comprising strings of memory cells comprises forming a conductor tier comprising conductor material on a substrate. A stack is formed comprising vertically-alternating first tiers and second tiers above the conductor tier. The stack comprises laterally-spaced memory-block regions having horizontally-elongated trenches there-between. Channel-material strings extend through the first tiers and the second tiers. Material of the first tiers is of different composition from that of the second tiers. A lowest of the first tiers is thicker than the first tiers there-above. The first-tier material is isotropically etched selectively relative to the second-tier material to form void-space in the first tiers. Conducting material is deposited into the trenches and into the void-space in the first tiers. The conducting material fills the void-space in the first tiers that are above the lowest first tier.

Abstract: A semiconductor device includes first and second semiconductor fins extending from a substrate and a source/drain region epitaxially grown in recesses of the first and second semiconductor fins. A top surface of the source/drain region is higher than a surface level with top surfaces of the first and second semiconductor fins. The source/drain region includes a plurality of buffer layers. Respective layers of the plurality of buffer layers are embedded between respective layers of the source/drain region.

Abstract: A semiconductor device and fabrication method are described for forming a nanosheet transistor device by forming a nanosheet transistor stack (12-18, 25) of alternating Si and SiGe layers which are selectively processed to form metal-containing current terminal or source/drain regions (27, 28) and to form control terminal electrodes (36A-D) which replace the SiGe layers in the nanosheet transistor stack and are positioned between the Si layers which form transistor channel regions in the nanosheet transistor stack to connect the metal source/drain regions, thereby forming a nanosheet transistor device.

Abstract: Multiple-patterning techniques described herein enable forming fin structures of a semiconductor device in a manner that enables decreased fin-to-fin spacing of the fin structures while providing precise control over etching depth of the fin structures. In some implementations, an etch operation is performed to form a pattern in one or more mask layers that is used to etch a substrate to form the fin structures. The etch operation includes an advanced pulsing technique, in which a high-frequency radio frequency (RF) source and a low-frequency RF source are pulsed. Pulsing the high-frequency RF source and the low-frequency RF source in the etch operation reduces consumption of a thickness of the one or more mask layers which increases the aspect ratio of the pattern. This enables deeper etching of the substrate when forming the fin structures, which reduces the likelihood of under etching.

Abstract: A method of forming a device on a silicon substrate having first, second and third areas includes recessing an upper substrate surface in the first and third areas, forming an upwardly extending silicon fin in the second area, forming first source, drain and channel regions in the first area, forming second source, drain and channel regions in the fin, forming third source, drain and channel regions in the third area, forming a floating gate over a first portion of the first channel region using a first polysilicon deposition, forming an erase gate over the first source region and a device gate over the third channel region using a second polysilicon deposition, and forming a word line gate over a second portion of the first channel region, a control gate over the floating gate, and a logic gate over the second channel region using a metal deposition.

Abstract: A semiconductor structure and a forming method thereof are provided.

Abstract: In a method for manufacturing a semiconductor device, an isolation insulating layer is formed over a fin structure. A first portion of the fin structure is exposed from and a second portion of the fin structure is embedded in the isolation insulating layer. A dielectric layer is formed over sidewalls of the first portion of the fin structure. The first portion of the fin structure and a part of the second portion of the fin structure in a source/drain region are removed, thereby forming a trench. A source/drain epitaxial structure is formed in the trench using one of a first process or a second process. The first process comprises an enhanced epitaxial growth process having an enhanced growth rate for a preferred crystallographic facet, and the second process comprises using a modified etch process to reduce a width of the source/drain epitaxial structure.

Abstract: A semiconductor structure and a method for forming the semiconductor structure are provided. The semiconductor structure includes a substrate including a first region and a second region, a first gate structure over the first region, and first source-drain doped layers in the first region of the substrate on both sides of the first gate structure. The semiconductor structure also includes a second gate structure over the second region, and second source-drain doped layers in the second region of the substrate on both sides of the second gate structure. Further, the semiconductor structure includes a first protection layer over the second gate structure, a first conductive structure over a first source-drain doped layer, and an isolation layer over the first conductive structure. The first conductive structure is also formed on the first gate structure, and the first conductive structure has a top surface lower than the first protection layer.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a bipolar transistor with thermal conductor and methods of manufacture. The structure includes: a base formed within a semiconductor substrate; a thermal conductive material under the base and extending to an underlying semiconductor material; an emitter on a first side of the base; and a collector on a second side of the base.

Abstract: A dual gate IGBT is presented, where the active region includes a first section and a second section. Both sections may be controlled by two control signals. For example, the first section exhibits a first characteristic transfer curve, load current in dependence of the voltage of the first control signal, and the second section exhibits a second characteristic transfer curve, load current in dependence of the voltage of the first control signal. At least the second characteristic transfer curves are changeable based on the voltage of the second control signal. For a given voltage of the first control signal corresponding to a forward-conduction-state of the power semiconductor device, the change of load current in the first section observed for a given change of the voltage of the second control signal is smaller as compared to the corresponding change of the load current in the second section.

Abstract: A semiconductor device includes a channel on a substrate. The channel includes a 2-dimensional material. A gate insulating layer is on a first portion of the channel. A gate electrode is on a portion of the gate insulating layer. First and second contact patterns are on second portions of the channel, respectively. Each of the first and second contact patterns includes a 2-dimensional material having an intercalation material disposed therein. First and second source/drain electrodes are on the first and second contact patterns, respectively. Each of the first and second source/drain electrodes includes a metal.