Abstract: A method for producing an FET transistor includes producing a transistor channel, comprising at least one semiconductor nanowire arranged on a substrate and comprising first and second opposite side faces; producing at least two dummy gates, each arranged against one of the first and second side faces of the channel; etching a first of the two dummy gates, forming a first gate location against the first side face of the channel; producing a first gate in the first gate location and against the first side face of the channel; etching a second of the two dummy gates, forming a second gate location against the second side face of the channel; and producing a second gate in the second gate location and against the second side face of the channel.

Abstract: A junction field effect transistor includes a first semiconductor layer of first conductivity type, an element isolation insulator disposed on the first semiconductor layer to partition an active area, a second semiconductor layer of second conductivity type, on the first semiconductor layer in the active area, and having an end in a first direction separated from the element isolation insulator, a source layer of second conductivity type, on the second semiconductor layer, the source layer having an impurity concentration higher than that of the second semiconductor layer, a drain layer of second conductivity type, on the second semiconductor layer, and separated from the source layer in a second direction, the drain layer having an impurity concentration higher than that of the second semiconductor layer, and a gate layer of first conductivity type, on the second semiconductor layer, and between and separated from the source and drain layers.

Abstract: Capacitor structures including a first island of a first conductive region and a second island of the first conductive region having a first conductivity type, an island of a second conductive region having a second conductivity type different than the first conductivity type, a dielectric overlying the first island of the first conductive region, a conductor overlying the dielectric, and a terminal of a diode overlying the second island of the first conductive region and overlying the island of the second conductive region.

Abstract: A neuromorphic system and a memory device are provided. The neuromorphic system includes input neurons that provide input signals, output neurons that provide output signals, and a plurality of synapse units provided at interconnecting points between the input neurons and the output neurons. Each of the synapse units has a structure in which a plurality of synapse elements are connected in parallel to each other between one input neuron among the input neurons and one output neuron among the output neurons. Both of a multi-level operation and information retention are satisfied. The weight of a synapse unit is gradually and symmetrically changed. The synapse elements are stacked in a 3D stack structure, thereby increasing the number of levels, which is able to be implemented, and thereby representing a high degree of integration.

Abstract: The present disclosure provides a semiconductor device including a substrate, a first active region, a second active region, and a gate structure. The first active region and the second active region are disposed in the substrate. The gate structure includes a bottom, a first sidewall attached to the first active region, and a second sidewall attached to the second active region. The first sidewall and the bottom have a first point of intersection, and the first sidewall and a first horizontal line starting from the first point toward the substrate have a first included angle. The second sidewall and the bottom have a second point of intersection, and the second sidewall and a second horizontal line starting from the second point toward the substrate have a second included angle. The first included angle is different from the second included angle. A method for manufacturing a semiconductor device is provided herein.

Abstract: Circuits employing an adjacent low-k dummy gate to a field-effect transistor (FET) to reduce FET source/drain parasitic capacitance, and related fabrication methods. To reduce or mitigate an increase in the source/drain parasitic capacitance(s) of a FET, a dummy gate adjacent to an active gate of the FET is provided to have a low-k (i.e., low relative permittivity). In this manner, the relative permittivity (k) between the source/drain of the FET and an adjacent dummy gate and/or source/drain of another FET is reduced, thereby reducing the parallel plate capacitance of the FET(s). Reducing parasitic capacitance of the FET(s) may allow further reduced scaling of the circuit to offset or mitigate a lack of reduction or increase in parasitic capacitance as a result of reducing gate pitch in the circuit. As gate pitch is reduced in the circuit, it may not be possible to proportionally reduce gate size without sacrificing gate control.

Abstract: A display device according to an exemplary embodiment includes: a first substrate; first data pads that are disposed in a first row extending along a first direction on the first substrate, second data pads that are disposed in a second row extending along the first direction on the first substrate, gate pads that are disposed in the first row and are not disposed in the second row on the first substrate, data lines that are connected with the first data pads and the second data pads on the first substrate, and control signal lines that are connected the gate pads, wherein the control signal lines extend in a side area of the second data pads from the gate pads.

Abstract: A method for manufacturing a semiconductor device includes forming a fin on a semiconductor substrate, and forming a bottom source/drain region adjacent a base of the fin. In the method, a dielectric layer, a work function metal layer and a first gate metal layer are sequentially deposited on the bottom source/drain region and around the fin. The dielectric layer, the work function metal layer and the first gate metal layer form a gate structure. The method also includes removing the dielectric layer, the work function metal layer and the first gate metal layer from an end portion of the fin, and depositing a second gate metal layer around the end portion of the fin in place of the removed dielectric layer, the removed work function metal layer and the removed first gate metal layer. The second gate metal layer contacts the end portion of the fin.

Abstract: A method of fabricating a semiconductor memory device includes etching a substrate that forms a trench that crosses active regions of the substrate, forming a gate insulating layer on bottom and side surfaces of the trench, forming a first gate electrode on the gate insulating layer that fills a lower portion of the trench, oxidizing a top surface of the first gate electrode where a preliminary barrier layer is formed, nitrifying the preliminary barrier layer where a barrier layer is formed, and forming a second gate electrode on the barrier layer that fills an upper portion of the trench.

Abstract: A transistor (100), including a planar semiconducting substrate (36), a source (42) formed on the substrate, a first drain (102) formed on the substrate, and a second drain (104) formed on the substrate in a location physically separated from the first drain. At least one gate (38, 40) is formed on the substrate and is configured to selectably apply an electrical potential to the substrate in either a first spatial pattern, which causes a first conductive path (62) to be established within the substrate from the source to the first drain, or a second spatial pattern, which causes a second conductive path to be established within the substrate from the source to the second drain.

Abstract: A tunable breakdown voltage RF MESFET and/or MOSFET and methods of manufacture are disclosed. The method includes forming a first line and a second line on an underlying gate dielectric material. The second line has a width tuned to a breakdown voltage. The method further includes forming sidewall spacers on sidewalls of the first and second line such that the space between first and second line is pinched-off by the dielectric spacers. The method further includes forming source and drain regions adjacent outer edges of the first line and the second line, and removing at least the second line to form an opening between the sidewall spacers of the second line and to expose the underlying gate dielectric material. The method further includes depositing a layer of material on the underlying gate dielectric material within the opening, and forming contacts to a gate structure and the source and drain regions.

Abstract: A GaAs (Gallium Arsenide) cell is provided. The GaAs cell comprises at least a GaAs substrates; a plurality of drain electrodes and a plurality of source electrodes, disposed on the at least a GaAs substrates; a gate electrode, disposed between the plurality of drain electrodes and the plurality of source electrodes, elongated along a first direction; a first anchor at a first end of the gate electrode; and a second anchor at a second end of the gate electrode; wherein a gate length of the gate electrode on a second direction is smaller than both a first width of the first anchor and a second width of the second anchor along the second direction.

Abstract: Devices, structures, and methods thereof for providing a Schottky or Schottky-like contact as a source region and/or a drain region of a power transistor are disclosed. A power transistor structure comprises a substrate of a first dopant polarity, a drift region formed on or within the substrate, a body region formed on or within the drift region, a gate structure formed on or within the substrate, a source region adjacent to the gate structure, a drain region formed adjacent to the gate structure. At least one of the source region and the drain region is formed from a Schottky or Schottky-like contact substantially near a surface of the substrate, comprising a silicide layer and an interfacial dopant segregation layer. The Schottky or Schottky-like contact is formed by low-temperature annealing a dopant segregation implant in the source and/or drain region.

Abstract: A technique for making high performance low noise amplifiers, low cost high performance RF, microwave circuits and other devices by using a minimum of costly high performance semiconductors is described. By combining a single discrete portion of an expensive semiconductor with a less expensive GaAs carrier, MMIC devices with improved performance over their discrete counterparts are achieved.

Abstract: A GaAs (Gallium Arsenide) cell is provided. The GaAs cell comprises a drain electrode and a source electrode, disposed on the GaAs substrate; a plurality of gate electrodes, disposed between the drain electrode and the source electrode, elongated on a first direction, wherein a gate electrode among the plurality of gate electrodes comprises a first end and a second end; a plurality of first anchors; a plurality of second anchors; wherein a first gate electrode and a second gate electrode among the plurality of gate electrodes are spaced by a gate-to-gate spacing, the first gate electrode and the drain electrode are spaced by a first gate-to-terminal spacing, and the gate-to-gate spacing is smaller than twice of the first gate-to-terminal spacing.

Abstract: A method of fabricating a semiconductor memory device includes etching a substrate that forms a trench that crosses active regions of the substrate, forming a gate insulating layer on bottom and side surfaces of the trench, forming a first gate electrode on the gate insulating layer that fills a lower portion of the trench, oxidizing a top surface of the first gate electrode where a preliminary barrier layer is formed, nitrifying the preliminary barrier layer where a barrier layer is formed, and forming a second gate electrode on the barrier layer that fills an upper portion of the trench.

Abstract: A power transistor is provided with at least one transistor finger that lies within a semiconductor material. The gate oxide is segmented into a set of segments with thick field oxide between each segment in order to reduce gate capacitance and thereby improve a resistance times gate charge figure of merit.

Abstract: A display device according to an embodiment includes a lower substrate in which a display area and a non-display area are divided and an upper substrate which corresponds to the lower substrate and includes a black matrix BM. Further, the display device can include a bezel which is located on the non-display area and includes a GIP driver, a plurality of signal transmission lines, a connection line connecting the GIP driver and the plurality of signal transmission lines, and a seal area equipped with a sealant, in a direction being apart from one side of the display area, a plurality of bridge patterns which is located on the non-display area and electrically connects the GIP driver and the connection line, and the connection line and the plurality of signal transmission lines, respectively, and a plurality of shield patterns enclosing the plurality of bridge patterns.

Abstract: A tunable breakdown voltage RF MESFET and/or MOSFET and methods of manufacture are disclosed. The method includes forming a first line and a second line on an underlying gate dielectric material. The second line has a width tuned to a breakdown voltage. The method further includes forming sidewall spacers on sidewalls of the first and second line such that the space between first and second line is pinched-off by the dielectric spacers. The method further includes forming source and drain regions adjacent outer edges of the first line and the second line, and removing at least the second line to form an opening between the sidewall spacers of the second line and to expose the underlying gate dielectric material. The method further includes depositing a layer of material on the underlying gate dielectric material within the opening, and forming contacts to a gate structure and the source and drain regions.

Abstract: A change in electrical characteristics can be suppressed and reliability can be improved in a semiconductor device including a transistor having an oxide semiconductor. A semiconductor device includes a transistor, and the transistor includes an oxide semiconductor film over a first insulating film, a gate insulating film over the oxide semiconductor film, a gate electrode over the gate insulating film, a conductive film in contact with a side surface of the gate electrode in a channel length direction, and a second insulating film over the oxide semiconductor film. The oxide semiconductor film includes a first region overlapping with the gate electrode, a second region overlapping with the conductive film, and a third region in contact with the second insulating film. The third region includes a region having higher impurity element concentration than the second region.

Abstract: Various embodiments are described that relate to a combined signal. A signal can be transmitted from a transmitter and be received by a receiver. The receiver can be an antenna array that comprises multiple individual antenna elements. At least some of these individual elements can receive the transmitted signal at different reception angles and these received signals can be considered signal copies. The reception angle can influence a power level of a signal copy. Multiple signal copies can be combined together into a combined signal that has a greater power level than the individual signal copies used in the combination.

Abstract: Provided is display panel including a substrate including a pixel area and a pad area; and a first conductive line and a second conductive line stacked on the substrate, wherein the first conductive line includes a first part disposed on the pixel area and a second part disposed on the pad area and the second conductive line includes a first part disposed on the pixel area and a second part disposed on the pad area. The first part of the first conductive line and the first part of the second conductive line are parallel to each other and the second part of the first conductive line and the second part of the second conductive line are overlapped vertically.

Abstract: A TFT, OLED display including the same, and manufacturing method thereof are disclosed. In one aspect, the TFT includes a first gate electrode formed over a substrate and a first insulating layer formed over the substrate and the first gate electrode. A semiconductor layer is formed over the first insulating layer, the semiconductor layer at least partially overlapping the first gate electrode. A second insulating layer is formed over the first insulating layer and the semiconductor layer, the first and second insulating layers having a pair of connection holes formed therethrough. A second gate electrode is electrically connected to the first gate electrode via the connection holes, the connection holes respectively exposing portions of the first gate electrode. Source and drain electrodes are formed over a third insulating layer and electrically connected to the semiconductor layer via the contact holes, the contact holes respectively exposing portions of the semiconductor layer.

Abstract: The present disclosure provides a FinFET device and method of fabricating a FinFET device. The method includes providing a substrate, forming a fin structure on the substrate, forming a gate structure including a gate dielectric and gate electrode, the gate structure overlying a portion of the fin structure, forming a protection layer over another portion of the fin structure, and thereafter performing an implantation process to form source and drain regions.

Abstract: A method for forming a semiconductor device includes forming a fin structure on a substrate, forming a shallow trench isolation region adjacent the fin structure so that an upper portion of the fin structure is exposed, forming a dummy gate over the exposed fin structure, forming an interlayer dielectric layer around the dummy gate, removing the dummy gate to expose the fin structure, and after removing the dummy gate, introducing a strain into a crystalline structure of the exposed fin structure.

Abstract: A method for forming a fin on a substrate comprises patterning and etching a layer of a first semiconductor material to define a strained fin, depositing a layer of a second semiconductor material over the fin, the second semiconductor material operative to maintain the a strain in the strained fin, etching to remove a portion of the second semiconductor material to define a cavity that exposes a portion of the fin, etching to remove the exposed portion of the fin such that the fin is divided into a first segment and a second segment, and depositing an insulator material in the cavity, the insulator material contacting the first segment of the fin and the second segment of the fin.

Abstract: A semiconductor device comprises a recessed access device that includes a first pillar, a second pillar, a channel region connecting the first and second pillars, and a gate disposed over the channel region. The channel region has a width that is narrower than widths of the first pillar and the second pillar. An array of recessed access devices comprises a plurality of pillars protruding from a substrate, and a plurality of channel regions. Each channel region has a width that is less than about 10 nm and couples neighboring pillars to form a plurality of junctionless recessed access devices. A method of forming at least one recessed access device also comprises forming pillars over a substrate, forming at least a channel region coupled with the pillars, the channel region having a relatively narrow width, and forming a gate at least partially surrounding the channel region on at least three sides.

Abstract: A pre-patterned substrate has a supporting material, a plurality of segments on the supporting material, a plurality of interdigitated line structures within each segment to allow formation of features, and an isolation region between the segments.

Abstract: A semiconductor memory device according to an embodiment comprises a stacked body, the stacked body including a plurality of conductive layers disposed on a semiconductor substrate and an inter-layer insulating film disposed between the plurality of conductive layers. A columnar semiconductor layer is surrounded as a stacking direction of the stacked body. An isolation film extends from an outer surface of the stacked body to a bottom of the stacked body and has a longitudinal direction in a second direction. At least some of the isolation films include a base portion extending in the second direction and a terminal portion positioned at an end of the base portion, and a width of the end in a third direction intersecting the second direction is larger than a width of the base portion.

Abstract: An organic light emitting diode display includes: a substrate; a semiconductor layer formed on the substrate and including a switching semiconductor layer, a driving semiconductor layer, and a light emission control semiconductor layer spaced apart from each other; a first gate insulating layer covering the semiconductor layer; a light emission control gate electrode formed on the first gate insulating layer and overlapping the light emission control semiconductor layer; a second gate insulating layer covering the light emission control gate electrode; a switching gate electrode and a driving gate electrode formed on the second gate insulating layer and respectively overlapping the switching semiconductor layer and the driving semiconductor layer; and an interlayer insulating layer covering the switching gate electrode, the driving gate electrode, and the second gate insulating layer.

Abstract: A junction gate field-effect transistor (JFET) includes a substrate, a source region formed in the substrate, a drain region formed in the substrate, a channel region formed in the substrate, and at least one gate region formed in the substrate. The channel region connects the source and drain regions. The at least one gate region is configured to cause a depletion region in one of the source and drain regions.

Abstract: Junction field-effect transistors and design structures for a junction field-effect transistor. A source and a drain of the junction field-effect transistor are comprised of a semiconductor material grown by selective epitaxy and in direct contact with a top surface of a semiconductor layer. A gate is formed that is aligned with a channel laterally disposed in the semiconductor layer between the source and the drain. The source, the drain, and the semiconductor layer are each comprised of a second semiconductor material having an opposite conductivity type from a first semiconductor material comprising the gate.

Abstract: One method disclosed includes removing at least a portion of a fin to thereby define a fin trench in a layer of insulating material, forming a substantially defect-free first layer of semiconductor material in the fin trench, forming a second layer of semiconductor material on an as-formed upper surface of the first layer of semiconductor material, forming an implant region at the interface between the first layer of semiconductor material and the substrate, performing an anneal process to induce defect formation in at least the first layer of semiconductor material, forming a third layer of semiconductor material on the second layer of semiconductor material, forming a layer of channel semiconductor material on the third layer of semiconductor material, and forming a gate structure around at least a portion of the channel semiconductor material.

Abstract: A method for simultaneously forming JFET devices and MOSFET devices on a substrate includes using gate structures which serve as active gate structures in the MOSFET region, as dummy gate structures in the JFET portion of the device. The dummy gate electrodes are used as masks and determine the spacing between gate regions and source/drain regions, the width of the gate regions, and the spacing between adjacent gate regions according to some embodiments. The transistor channel is therefore accurately dimensioned.

Abstract: An electrical contact structure distributes current along a length thereof. The electrical contact structure includes a plurality of n metal rectangles on n levels of metal. The rectangle on one metal level is at least as wide in width and vertically covers in width the rectangle on the metal level immediately below. The rectangle on one metal level is shorter in length than and substantially aligned at a first end with the rectangle on the metal level immediately below. Rectangle first ends are substantially aligned. Features of an exemplary FET transistor of this invention are a source and drain terminal electrical contact structure, a multi-level metal ring connecting gate rectangles on both ends, and a wider-than-minimum gate-to-gate spacing. The invention is useful, for example, in an electromigration-compliant, high performance transistor.

Abstract: A high voltage JFET has a deep well of a first type of conductivity made in a semiconductor substrate, a further well of an opposite second type of conductivity arranged in the deep well, a shallow well of a first type of conductivity arranged in the further well, a first contact region for source and a second contact region for drain arranged in the further well, a third contact region for gate arranged between the first contact region and the second contact region in the shallow well, a first distance between the first contact region and the third contact region being smaller than a second distance between the second contact region and the third contact region, and an electrical connection between the first contact region and the second contact region via at least one channel region present between the deep well and the shallow well in the further well.

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

Abstract: A composite high dielectric constant (high-k) gate dielectric includes a stack of a doped high-k gate dielectric and an undoped high-k gate dielectric. The doped high-k gate dielectric can be formed by providing a stack of a first high-k dielectric material layer and a dopant metal layer and annealing the stack to induce the diffusion of the dopant metal into the first high-k dielectric material layer. The undoped high-k gate dielectric is formed by subsequently depositing a second high-k dielectric material layer. The composite high-k gate dielectric can provide an increased gate-leakage oxide thickness without increasing inversion oxide thickness.

Abstract: The present application discloses a semiconductor device comprising a source region and a drain region in an ultra-thin semiconductor layer; a channel region between the source region and the drain region in the ultra-thin semiconductor layer; a front gate stack above the channel region, the front gate comprising a front gate and a front gate dielectric between the front gate and the channel region; and a back gate stack below the channel region, the back gate stack comprising a back gate and a back gate dielectric between the back gate and the channel region, wherein the front gate is made of a high-Vt material, and the back gate is made of a low-Vt material. According to another embodiment, the front gate and the back gate are made of the same material, and the back gate is applied with a forward bias voltage during operation. The semiconductor device alleviates threshold voltage fluctuation due to varied thickness of the channel region by means of the back gate.

Abstract: A method of forming a junction field effect transistor, the transistor comprising: a back gate; a channel; a top gate; a drain and a source in current flow with the channel; wherein the method comprises selecting a first channel dimension between the top gate and the back gate such that a significant current flow path in the channel occurs in a region of relatively low electric field strength.

Abstract: A thin film transistor array substrate capable of reducing degradation of a device due to degradation of an oxide semiconductor pattern and a method of fabricating the same are provided. The thin film transistor array substrate may include an insulating substrate on which a gate electrode is formed, a gate insulating film formed on the insulating substrate, an oxide semiconductor pattern disposed on the gate insulating film, an anti-etching pattern formed on the oxide semiconductor pattern, and a source electrode and a drain electrode formed on the anti-etching pattern. The oxide semiconductor pattern may include an edge portion positioned between the source electrode and the drain electrode, and the edge portion may include at least one conductive region and at least one non-conductive region.

Abstract: A method for fabricating a semiconductor device utilizing a plurality of masks and spacers. The method includes forming parallel first trenches in a substrate using a first lithographic process. The substrate includes sidewalls adjacent to the parallel first trenches. Forming first spacers adjacent to the sidewalls. Removing the sidewalls, which in part includes using a second lithographic process. Forming second spacers adjacent to the first spacers, resulting in spacer ridges. Etching portions of the substrate between the spacer ridges resulting in second trenches.

Abstract: The present disclosure relates to methods of forming a self-aligned contact and related apparatus. In some embodiments, the method forms a plurality of gate lines interspersed between a plurality of dielectric lines, wherein the gate lines and the dielectric lines extend in a first direction over an active area. One or more of the plurality of gate lines are into a plurality of gate line sections aligned in the first direction. One or more of the plurality of dielectric lines are cut into a plurality of dielectric lines sections aligned in the first direction. A dummy isolation material is deposited between adjacent dielectric sections in the first direction and between adjacent gate line sections in the first direction. One or more self-aligned metal contacts are then formed by replacing a part of one or more of the plurality of dielectric lines over the active area with a contact metal.

Abstract: On a p? epitaxial layer, an n-type epitaxial layer and a gate region are formed in this order. A gate electrode is electrically connected to the gate region, and a source electrode and a drain electrode are spaced apart from each other with the gate electrode sandwiched therebetween. A control electrode is used for applying to the p? epitaxial layer a voltage that causes a reverse biased state of the p? epitaxial layer and the n-type epitaxial layer in an OFF operation.

Abstract: A semiconductor device may include a semiconductor substrate with first and second spaced apart source/drain regions defining a channel region therebetween and a control gate structure on the channel region between the first and second spaced apart source/drain regions. More particularly, the control gate structure may include a first gate electrode on the channel region adjacent the first source/drain region, and a second gate electrode on the channel region adjacent the second source/drain region. Moreover, the first and second gate electrodes may be electrically isolated. Related devices, structures, methods of operation, and methods of fabrication are also discussed.

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

Abstract: A field effect transistor including: a support layer, a plurality of active zones based on a semiconductor, each active zone configured to form a channel and arranged between two gates adjacent to each other and consecutive, the active zones and the gates being arranged on the support layer, each gate including a first face on the side of the support layer and a second face opposite the first face. The second face of a first of the two gates is electrically connected to a first electrical contact made on the second face of the first of the two gates, and the first face of a second of the two gates is electrically connected to a second electrical contact passing through the support layer. The gates of the transistor are not electrically connected to each other.

Abstract: A ring-shaped transistor includes a set of gates. Each gate of the set is disposed between a corresponding source and a corresponding drain. The set of gates are arranged such that all of the set of gates cannot be aligned with fewer than three imaginary straight lines drawn through the gates, with one of the imaginary straight lines passing only once though each of the set of gates.

Abstract: A gate conductor structure is provided having a barrier region between a N-type device and a P-type device, wherein the barrier region minimizes or eliminates cross-diffusion of dopant species across the barrier region. The barrier region comprises at least one sublithographic gap in the gate conductor structure. The sublithographic gap is formed by using self-assembling copolymers to form a sublithographic patterned mask over the gate conductor structure. According to one embodiment, at least one sublithographic gap is a slit or line that traverses the width of the gate conductor structure. The sublithographic gap is sufficiently deep to minimize or prevent cross-diffusion of the implanted dopant from the upper portion of the gate conductor. According to another embodiment, the sublithographic gaps are of sufficient density that cross-diffusion of dopants is reduced or eliminated during an activation anneal such that changes in Vt are minimized.

Abstract: A bidirectional switching device includes a semiconductor multilayer structure made of a nitride semiconductor, a first ohmic electrode and a second ohmic electrode which are formed on the semiconductor multilayer structure, and a first gate electrode and a second gate electrode. The first gate electrode is covered with a first shield electrode having a potential substantially equal to that of the first ohmic electrode. The second gate electrode is covered with the second shield electrode having a potential substantially equal to that of the second ohmic electrode. An end of the first shield electrode is positioned between the first gate electrode and the second gate electrode, and an end of the second shield electrode is positioned between the second gate electrode and the first gate electrode.