Abstract: Structures for a high-electron-mobility transistor and methods of forming such structures. The structure comprises a device structure including a gate and an ohmic contact, and one or more inactive blocks laterally positioned between the gate and the ohmic contact.

Abstract: A method for forming a high electron mobility transistor includes the steps of forming an epitaxial stack on a substrate, forming a gate structure on the epitaxial stack, forming an insulating layer covering the epitaxial stack and the gate structure, forming a passivation layer on the insulating layer, forming an opening on the gate structure and through the passivation layer to expose the insulating layer, and removing a portion of the insulating layer through the opening to form an air gap between the gate structure and the passivation layer.

Abstract: Disclosed are an enhancement-mode device and a preparation method therefor. The enhancement-mode device adopts a vertical or semi-vertical structure, and a nitride heterojunction with a non-polar surface or semi-polar face is prepared, such that two-dimensional electron gas is interrupted at the position, and the enhancement-mode device is obtained.

Abstract: Some embodiments of the disclosure provide a semiconductor device. The semiconductor device comprises: a substrate; a first nitride semiconductor layer disposed on the substrate; a second nitride semiconductor layer disposed on the first nitride semiconductor layer and having a bandgap greater than that of the first nitride semiconductor layer; an ohmic contact disposed on the first nitride semiconductor layer; and a spacer disposed adjacent to a sidewall of the ohmic contact.

Abstract: A GaN-HEMT device with a sandwich structure and a method for preparing the same are provided. The GaN-HEMT device includes an epitaxial layer and electrodes, wherein the epitaxial layer includes a GaN channel layer (2) and an AlyGa1-y barrier layer (1), and is arranged from top to bottom; the electrodes include a gate electrode (6), a source electrode (7), a drain electrode (5) and a field plate electrode (10), wherein the field plate electrode (10) and the gate electrode (6) are respectively fabricated on an upper surface and a lower surface of the epitaxial layer, and the field plate electrode (10) extends to a region beyond the epitaxial layer and is connected with the gate electrode (6) to form the sandwich structure, and the source electrode (7) and the drain electrode (5) are respectively located at two ends of the epitaxial layer.

Abstract: A semiconductor device structure and a method for forming a semiconductor device structure are provided. The semiconductor device structure includes a stack of channel structures over a base structure. The semiconductor device structure also includes a first epitaxial structure and a second epitaxial structure sandwiching the channel structures. The semiconductor device structure further includes a gate stack wrapped around each of the channel structures and a backside conductive contact connected to the second epitaxial structure. A first portion of the backside conductive contact is directly below the base structure, and a second portion of the backside conductive contact extends upwards to approach a bottom surface of the second epitaxial structure. In addition, the semiconductor device structure includes an insulating spacer between a sidewall of the base structure and the backside conductive contact.

Abstract: A semiconductor device includes a substrate, a semiconductor channel layer, a semiconductor barrier layer, a gate electrode, a first electrode, and a dielectric layer. The semiconductor channel layer is disposed on the substrate, and the semiconductor barrier layer is disposed on the semiconductor channel layer. The gate electrode is disposed on the semiconductor barrier layer. The first electrode is disposed at one side of the gate electrode. The first electrode includes a body portion and a vertical extension portion. The body portion is electrically connected to the semiconductor barrier layer, and the bottom surface of the vertical extension portion is lower than the top surface of the semiconductor channel layer. The dielectric layer is disposed between the vertical extension portion and the semiconductor channel layer.

Abstract: To prevent the surface of a base substrate and the bottom surface of a separated semiconductor epitaxial layer from being bonded to each other even after a removal layer is removed, the semiconductor substrate includes a base substrate, a first removal layer provided on the base substrate, a second removal layer provided above the first removal layer, and a semiconductor epitaxial layer provided above the second removal layer, and an etching rate of the second removal layer for a predetermined etching material is larger than the etching rate of the first removal layer for the predetermined etching material.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to gate structures and methods of manufacture. The structure includes: a gate structure comprising a horizontal portion and a substantially vertical stem portion; and an air gap surrounding the substantially vertical stem portion and having a curved surface under the horizontal portion.

Abstract: RF amplifiers are provided that include an interconnection structure and a Group III nitride-based RF amplifier die that is mounted on top of the interconnection structure. The Group III nitride-based RF amplifier die includes a semiconductor layer structure. A plurality of unit cell transistors are provided in an upper portion of the semiconductor layer structure, and a gate terminal, a drain terminal and a source terminal are provided on a lower surface of the semiconductor layer structure that is adjacent the interconnection structure.

Abstract: The present disclosure provides a semiconductor device and a fabrication method thereof. The semiconductor device includes a first nitride semiconductor layer, a second nitride semiconductor layer, a doped group III-V semiconductor layer and a gate layer. The first nitride semiconductor layer has a first surface. The second nitride semiconductor layer is formed on the first surface of the first nitride semiconductor layer and has a greater bandgap than that of the first nitride semiconductor layer. The doped group III-V semiconductor layer is over the second nitride semiconductor layer. The doped group III-V semiconductor layer includes a first portion and a second portion having different thicknesses. The gate layer is disposed on the first portion and the second portion of the doped group III-V semiconductor layer.

Abstract: A semiconductor device includes at least one transistor disposed on or in a substrate. The transistor is a bipolar transistor including an emitter, a base, and a collector, or a field-effect transistor including a source, a gate, and a drain. At least one first bump connected to the emitter or the source is disposed on the substrate. Furthermore, at least three second bumps connected to the collector or the drain are disposed on the substrate. In plan view, a geometric center of the at least one first bump is located inside a polygon whose vertices correspond to geometric centers of the at least three second bumps.

Abstract: The present disclosure provides a semiconductor device and a fabrication method thereof. The semiconductor device includes a substrate, a channel layer disposed on the substrate, and a barrier layer disposed on the channel layer. The semiconductor device further includes a dielectric layer disposed on the barrier layer and defining a first recess exposing a portion of the barrier layer. The semiconductor device further includes a first spacer disposed within the first recess, wherein the first spacer comprises a surface laterally connecting the dielectric layer to the barrier layer.

Abstract: A transistor amplifier includes a group III-nitride based amplifier die including a gate terminal, a drain terminal, and a source terminal on a first surface of the amplifier die and an interconnect structure electrically bonded to the gate terminal, drain terminal and source terminal of the amplifier die on the first surface of the amplifier die and electrically bonded to an input path and output path of the transistor amplifier.

Abstract: A disclosed semiconductor device includes an electron transit layer; an electron supply layer disposed above the electron transit layer; a source electrode, a drain electrode, and a gate electrode, the source electrode, the drain electrode, and the gate electrode being disposed on the electron supply layer; a first capping layer disposed on the electron supply layer between the gate electrode and the drain electrode; and a negative charge generation layer disposed on the first capping layer, the negative charge generation layer being configured to generate a negative charge.

Abstract: Described herein are III-N (e.g. GaN) devices having a stepped cap layer over the channel of the device, for which the III-N material is orientated in an N-polar orientation.

Abstract: A semiconductor structure and a method for forming a semiconductor structure are provided. A sacrificial gate layer is removed to form a gate trench exposing a sacrificial dielectric layer. An ion implantation is performed to a portion of a substrate covered by the sacrificial dielectric layer in the gate trench. The sacrificial dielectric layer is removed to expose the substrate from the gate trench. An interfacial layer is formed over the substrate in the gate trench. A metal gate structure is formed over the interfacial layer in the gate trench.

Abstract: A semiconductor structure and a manufacturing method of the semiconductor structure are provided. The semiconductor structure includes a substrate and a III-V group compound layer disposed on the substrate. The III-V group compound layer has n trenches vertically communicating with each other, and n?2. Widths of the n trenches gradually decrease from the width of the uppermost first trench to the width of the lowermost nth trench, and the nth trench exposes a portion of the substrate.

Abstract: A resist (4) is applied on a semiconductor substrate (1) and a first opening (5) and a second opening (6) whose width is narrower than that of the first opening (5) are formed at the resist (4). The semiconductor substrate (1) is wet-etched using the resist (4) as a mask to form one continuous recess (7) below the first opening (5) and the second opening (6). After forming the recess (7), a shrink material (8) is cross-linked with the resist (4) to block the second opening (6) without blocking the first opening (5). After blocking the second opening (6), a gate electrode (11) is formed within the recess (7) via the first opening (5).

Abstract: A semiconductor device with a reduced tail current is provided. The semiconductor device includes a first junction field effect transistor. The first junction field effect transistor includes a drift layer of a first conductivity type, a first source region of the first conductivity type, a first gate region of a second conductivity type, a first drain region of the first conductivity type, a semiconductor region of the second conductivity type, and a control electrode. The first source region is provided in the semiconductor region. The control electrode is electrically connected to the semiconductor region.

Abstract: Radio frequency and microwave devices and methods of use are provided herein. According to some embodiments, the present technology may comprise an ohmic layer for use in a field effect transistor that includes a plurality of strips disposed on a substrate, the plurality of strips comprising alternating source strips and drain strips, with adjacent strips being spaced apart from one another to form a series of channels, a gate finger segment disposed in each of the series of channels, and a plurality of gate finger pads disposed in an alternating pattern around a periphery of the plurality of strips such that each gate finger segment is associated with two gate finger pads.

Abstract: Radio frequency and microwave devices and methods of use are provided herein. According to some embodiments, the present technology may comprise an ohmic layer for use in a field effect transistor that includes a plurality of strips disposed on a substrate, the plurality of strips comprising alternating source strips and drain strips, with adjacent strips being spaced apart from one another to form a series of channels, a gate finger segment disposed in each of the series of channels, and a plurality of gate finger pads disposed in an alternating pattern around a periphery of the plurality of strips such that each gate finger segment is associated with two gate finger pads.

Abstract: Vertically stacked Field Effect Transistors (FETs) are created where a first FET and a second FET are controllable independently. The vertically stacked FETs may be connected in series or in parallel, thereby suitable for use as a portion of a NAND circuit or a NOR circuit. Epitaxial growth over a source and drain of a first FET, and having similar doping to the source and drain of the first FET provide a source and drain of a second FET. An additional epitaxial growth of a type opposite the doping of the source and drain of the first FET provides a body for the second FET.

Abstract: A III-N device is described with a III-N material layer, an insulator layer on a surface of the III-N material layer, an etch stop layer on an opposite side of the insulator layer from the III-N material layer, and an electrode defining layer on an opposite side of the etch stop layer from the insulator layer. A recess is formed in the electrode defining layer. An electrode is formed in the recess. The insulator can have a precisely controlled thickness, particularly between the electrode and III-N material layer.

Abstract: Various aspects of the technology provide for a converter circuit such as a dc-dc voltage converter or buck converter. The circuit includes a enhancement mode control Field Effect Transistor (FET) fabricated using gallium arsenide and an depletion mode sync FET fabricated using gallium arsenide. A drain of the sync FET may be coupled to a source of the control FET and an inductor may be coupled to the source of the control FET and the drain of the sync FET.

Abstract: A field effect transistor (FET) having a source, a drain and a gate includes a first connection electrically connected to the gate near a first end of the gate, a second connection electrically connected to the gate near the first end of the gate, a third connection electrically connected to the gate near a second end of the gate, and a fourth connection electrically connected to the gate near the second end of the gate. By performing gate resistance measurements at different ambient temperatures, a thermal coefficient of gate resistance can be derived and then used to monitor the gate temperature, which is representative of the channel temperature.

Abstract: Circuits and systems comprising one or more switches are provided. A circuit includes a first switch formed on a substrate; and a second switch formed on the substrate, the second switch including a first terminal coupled to a third terminal of the first switch. A system includes a supply; a first switch formed on a substrate, the first switch coupled to the supply; a second switch formed on the substrate, the second switch coupled to the first switch; a third switch formed on the substrate, the third switch coupled to the supply; a fourth switch formed on the substrate, the fourth switch coupled to the third switch; and a driver coupled to respective second terminals of the first, second, third, and fourth switches.

Abstract: Various aspects of the technology provide for clamping a transient from a transient generator in a circuit using a Field Effect Transistor (FET) including a compound semiconductor layer forming a drain coupled to the transient voltage generator, a source, and a gate. The gate and the drain may be configured to clamp voltage transients in the circuit from the transient voltage generator independent of a clamping diode between the source and the drain. The FET may be a depletion mode type fabricated using germanium or a compound semiconductor such as gallium arsenide (GaAs) or gallium nitride (GaN).

Abstract: Circuits and systems comprising one or more switches are provided. A circuit includes a first switch formed on a substrate; and a second switch formed on the substrate, the second switch including a first terminal coupled to a third terminal of the first switch. A system includes a supply; a first switch formed on a substrate, the first switch coupled to the supply; a second switch formed on the substrate, the second switch coupled to the first switch; a third switch formed on the substrate, the third switch coupled to the supply; a fourth switch formed on the substrate, the fourth switch coupled to the third switch; and a driver coupled to respective second terminals of the first, second, third, and fourth switches.

Abstract: A horizontal semiconductor device includes a semiconductor substrate of a first conductivity type and a semiconductor region of a second conductivity type on the semiconductor substrate. The device includes a collector layer of the first conductivity type within the semiconductor region, an endless base layer of the first conductivity type within the semiconductor region, and an endless first emitter layer of the second conductivity type in the endless base layer. The endless base layer is off the collector layer but surrounds the collector layer. A movement of carriers between the endless first emitter layer and the collector layer is controlled in a channel region formed in the endless base layer. An insulation film is disposed between the semiconductor substrate and the semiconductor region. A region of the first conductivity type is disposed in the semiconductor region to contact with a surface of the endless base layer nearest the semiconductor substrate.

Abstract: An undoped AlGaN layer 13 is formed on a buffer layer composed of a GaN series material formed on a semiconductor substrate, a drain electrode 15 and a source electrode 16 forming ohmic junction with the undoped AlGaN layer 13 are formed separately from each other on the undoped AlGaN layer 13. A gate electrode 17 composed of metal Ni and Au laminated in this order is formed between the drain electrodes 15 and the source electrode 16 on the undoped AlGaN layer 13. The end portion 17-2 of the gate electrode 17 is formed on the underlying metal 18 formed by a metal containing Ti via an insulating film 14 on a GaN buffer layer 12 surrounding the undoped AlGaN layer 13.

Abstract: A peripheral circuit area is formed around a memory cell array area. The peripheral circuit area has element regions, an element isolation region isolating the element regions, and field-effect transistor formed in each of the element regions and including a gate electrode extending in a channel width direction, on a semiconductor substrate. An end portion and a corner portion of the gate electrode are on the element isolation region. A radius of curvature of the corner portion of the gate electrode is smaller than a length from the end portion of the element region in the channel width direction to the end portion of the gate electrode in the channel width direction, and is less than 85 nm.

Abstract: Semiconductor devices including a plurality of unit cells connected in parallel are provided. Each of the unit cells have a first electrode, a second electrode and a gate finger. One of the first electrodes at a center of the semiconductor device has a first width and one of the first electrodes at a periphery of the semiconductor device has a second width, smaller than the first width. The second electrodes have a substantially constant width such that a pitch between the gate fingers is non-uniform. Related methods are also provided.

Abstract: A III-nitride power device that includes a Schottky electrode surrounding one of the power electrodes of the device.

Abstract: A field-effect transistor (FET) with a round-shaped nano-wire channel and a method of manufacturing the FET are provided. According to the method, source and drain regions are formed on a semiconductor substrate. A plurality of preliminary channel regions is coupled between the source and drain regions. The preliminary channel regions are etched, and the etched preliminary channel regions are annealed to form FET channel regions, the FET channel regions having a substantially circular cross-sectional shape.

Abstract: A semiconductor device can be manufactured by a method that includes forming a structure that includes a plurality of layers of semiconductor material. One or more etching processes are performed on the multi-layered semiconductor structure, and then an Ar/O2 treatment is performed on the multi-layered semiconductor structure. The Ar/O2 treatment includes exposure of the structure to Ar ion bombardment and O2 molecular oxidation. The Ar/O2 treatment can be used to create a bottle-shaped structure.

Abstract: An undoped AlGaN layer 13 is formed on a buffer layer composed of a GaN series material formed on a semiconductor substrate, a drain electrode 15 and a source electrode 16 forming ohmic junction with the undoped AlGaN layer 13 are formed separately from each other on the undoped AlGaN layer 13. A gate electrode 17 composed of metal Ni and Au laminated in this order is formed between the drain electrodes 15 and the source electrode 16 on the undoped AlGaN layer 13. The end portion 17-2 of the gate electrode 17 is formed on the underlying metal 18 formed by a metal containing Ti via an insulating film 14 on a GaN buffer layer 12 surrounding the undoped AlGaN layer 13.

Abstract: A metal silicide in sophisticated semiconductor devices may be provided in a late manufacturing stage on the basis of contact openings, wherein the deposition of the contact material, such as tungsten, may be efficiently combined with the silicidation process. In this case, the thermally activated deposition process may initiate the formation of a metal silicide in highly doped semiconductor regions.

Abstract: Gate spacers are formed in FinFETS having a bottom portion of a first material extending to the height of the fins, and a top portion of a second material extending above the fins. An embodiment includes forming a fin structure on a substrate, the fin structure having a height and having a top surface and side surfaces, forming a gate substantially perpendicular to the fin structure over a portion of the top and side surfaces, for example over a center portion, forming a planarizing layer over the gate, the fin structure, and the substrate, removing the planarizing layer from the substrate, gate, and fin structure down to the height of the fin structure, and forming spacers on the fin structure and on the planarizing layer, adjacent the gate.

Abstract: A field plate portion (5) overhanging a drain side in a visored shape is formed in a gate electrode (2). A multilayered film including a SiN film (21) and a SiO2 film (22) is formed beneath the field plate portion (5). The SiN film (21) is formed so that a surface of an AlGaN electron supply layer (13) is covered therewith.

Abstract: A field effect transistor includes: a first nitride semiconductor layer having a plane perpendicular to a (0001) plane or a plane tilted with respect to the (0001) plane as a main surface; a second nitride semiconductor layer formed on the first nitride semiconductor layer and having a wider bandgap than the first nitride semiconductor layer; a third nitride semiconductor layer formed on the second nitride semiconductor layer; and a source electrode and a drain electrode formed so as to contact at least a part of the second nitride semiconductor layer or the third nitride semiconductor layer. A recess that exposes a part of the second nitride semiconductor layer is formed between the source electrode and the drain electrode in the third nitride semiconductor layer. A gate electrode is formed in the recess and an insulating film is formed between the third nitride semiconductor layer and the gate electrode.

Abstract: At least two drain ohmic contacts are arranged to intersect with an active area. A source ohmic contact is arranged between the drain ohmic contacts. A drain coupling portion on an element separating area couples ends of the drain ohmic contacts on the same side thereof. A gate power supply wiring on the element separating area couples gate fingers at the end thereof on the opposite side of the arrangement side of the drain coupling portion. A gate edge coupling portion couples two gate fingers adjacent to each other, sandwiching the source ohmic contact at the end thereof on the arrangement side of the drain coupling portion. The gate edge coupling portion does not intersect with the drain ohmic contact and the drain coupling portion.

Abstract: An n type impurity region is continuously formed on the bottom portion of a channel region below a source region, a gate region and a drain region. The n type impurity region has an impurity concentration higher than the channel region and a back gate region, and is less influenced by the diffusion of p type impurities from the gate region and the back gate region. Moreover, by continuously forming the impurity region from a portion below the source region to a portion below the drain region, the resistance value of a current path in the impurity region is substantially uniformed. Therefore, the IDSS is stabilized, the forward transfer admittance gm and the voltage gain Gv are improved, and the noise voltage Vno is decreased. Furthermore, the IDSS variation within a single wafer is suppressed.

Abstract: A semiconductor storage device has a plurality of word lines formed with a predetermined interval on a semiconductor substrate, a selection transistor provided at an end portion of the plurality of word lines, a first insulating film formed so as to cover side surfaces of the word lines, a side surface of the selection transistor, and a surface of the semiconductor substrate between the word lines, a high-permittivity film formed on the first insulation film, a second insulating film formed so as to cover the upper surface of the word lines and the selection transistor, a first air-gap portion located between the word lines and surrounded by the high-permittivity film and the second insulating film, and a second air-gap portion formed via the first insulating film and the high-permittivity film at a sidewall portion, which opposes the selection transistor, of the word line adjacent to the selection transistor, an upper portion of the second air-gap portion being covered by the second insulating film.

Abstract: An object of the present invention is to simplify manufacturing process of an n channel MIS transistor and a p channel MIS transistor with gate electrodes formed of a metal material. For its achievement, gate electrodes of each of the n channel MIS transistor and the p channel MIS transistor are simultaneously formed by patterning ruthenium film deposited on a gate insulator. Next, by introducing oxygen into each of the gate electrodes, the gate electrodes are transformed into those having high work function. Thereafter, by selectively reducing the gate electrode of the n channel MIS transistor, it is transformed into a gate electrode having low work function.

Abstract: A microelectronic device includes a metal gate with a metal gate upper surface. The metal gate is disposed in an interlayer dielectric first layer. The interlayer dielectric first layer also has an upper surface that is coplanar with the metal gate upper surface. A dielectric etch stop layer is disposed on the metal gate upper surface but not on the interlayer dielectric first layer upper surface.

Abstract: Semiconductor devices whose current characteristics can be prevented from varying even if a phase shift mask is used for patterning gate electrodes of MISFETs, and a manufacturing method thereof are disclosed. According to one aspect of the present invention, there is provided a semiconductor device comprising a first transistor including a first gate electrode provided above a semiconductor substrate, and a first source and a first drain provided in the semiconductor substrate, a second transistor arranged to be adjacent to the first transistor, and including a second gate electrode provided above the semiconductor substrate in parallel with the first gate electrode, and a second source and a second drain provided in the semiconductor substrate, and a third gate electrode provided between the first transistor and the second transistor and in parallel with the first and second gate electrodes.

Abstract: A method for reducing contact to gate shorts in a semiconductor device and the resulting semiconductor device are described. In one embodiment, a gate is formed on a substrate, a contact is formed on the gate and the substrate, and an insulator is formed between the gate and the contact. The insulator may be formed by oxidizing the gate to form a dielectric between the contact and the gate after the contact is formed on the gate.

Abstract: A semiconductor device and method is provided that has a stress component for increased device performance. The method integrates a stress material into a trench used typically for an isolation structure. The method includes forming an isolation trench through a SOI layer and an underlying BOX layer. The method further includes filling the isolation trench with stress material having characteristics different than the BOX layer.

Abstract: Provided are a stack structure including an epitaxial graphene, a method of forming the stack structure, and an electronic device including the stack structure. The stack structure includes: a Si substrate; an under layer formed on the Si substrate; and at least one epitaxial graphene layer formed on the under layer.