Abstract: A semiconductor device includes a semiconductor layer having a first plane and a second plane; an emitter electrode on a side of the first plane; at least one collector electrode on a side of the second plane; a first gate electrode on the side of the first plane; at least one second gate electrode on the side of the second plane; a drift region of a first conductivity-type in the semiconductor layer; a collector region of a second conductivity-type in the semiconductor layer; and a first conductivity-type region of the first conductivity-type provided between a part of the collector region and the second plane, wherein the semiconductor device has a first effective gate distance and a second effective gate distance different from the first effective gate distance.

Abstract: A semiconductor device is provided, including: a semiconductor substrate; a first-conductivity-type drift region provided in the semiconductor substrate; a gate trench portion extending in a predetermined extending direction in a plane of the upper surface of the semiconductor substrate; a mesa portion provided in contact with the gate trench portion in an array direction orthogonal to the extending direction; a first-conductivity-type accumulation region provided above the drift region and in contact with the gate trench portion, and having a higher doping concentration than the drift region; a second-conductivity-type base region provided above the accumulation region and in contact with the gate trench portion; and a second-conductivity-type floating region provided below the accumulation region and in contact with the gate trench portion, and provided in a part of the mesa portion in the array direction.

Abstract: A silicon carbide semiconductor device includes first semiconductor areas and second semiconductor areas. The first semiconductor areas have a first semiconductor layer of a second conductivity type, a second semiconductor layer of a first conductivity type, first semiconductor regions of the second conductivity type, second semiconductor regions of the first conductivity type, gate electrodes, and first electrodes. The second semiconductor areas have the first semiconductor layer, the second semiconductor layer, third semiconductor regions of the second conductivity type, the gate electrodes, and the first electrodes. The first semiconductor regions include low- impurity-concentration regions and high-impurity-concentration regions. The third semiconductor regions have a potential equal to that of the first electrodes. The first semiconductor regions are connected to the third semiconductor regions by MOS structures.

Abstract: A transistor device having reduced electrical field at the gate oxide interface is disclosed. In one embodiment, the transistor device comprises a gate, a source, and a drain, wherein the gate is at least partially in contact with a gate oxide. The transistor device has a P+ region within a JFET region of the transistor device in order to reduce an electrical field on the gate oxide.

Abstract: An electronic circuit including a bipolar switching memory device including first and second electrodes at terminals of which a programming voltage can be applied, the circuit including: a first mechanism applying, to the first electrode, a data signal having, during a time period d, a constant state 0 or 1; a second mechanism applying, to the second electrode, a control signal that alternates, during time period d, between state 1 and state 0, the control signal being same regardless of the state in which the memory device is programmed; a selection device allowing a current to flow into the memory device during a programming time included in time period d; and a change of state of the control signal taking place during the programming time.

Abstract: An optical device for detecting a first chemical species and a second chemical species contained in a specimen, which includes: a first optical sensor, which may be optically coupled to an optical source through the specimen and is sensitive to radiation having a wavelength comprised in a first range of wavelengths; and a second optical sensor, which may be optically coupled to the optical source through the specimen and is sensitive to radiation having a wavelength comprised in a second range of wavelengths, different from the first range of wavelengths.

Abstract: A fourth impurity region includes a first region facing a bottom portion of a trench and a part of a second impurity region and a second region facing the second impurity region. A first impurity region includes a third region in contact with a side surface of the trench, the second impurity region, the first region, and a second region and a fourth region which is located on a side of a second main surface relative to the third region, electrically connected to the third region, and lower in impurity concentration than the third region. A surface of the first region facing the second main surface is located on the side of the second main surface in a direction perpendicular to the second main surface relative to a surface of the second region facing the second main surface.

Abstract: Some embodiments relate to a semiconductor device. The semiconductor device includes a drain region and a channel region surrounding the drain region. A source region surrounds the channel region such that the channel region separates the drain region from the source region. A gate electrode is arranged over the channel region and has an inner edge proximate to the drain. A resistor structure, which is made up of a curved or polygonal path of resistive material, is arranged over the drain and is coupled to the drain. The resistor structure is perimeterally bounded by the inner edge of the gate electrode.

Abstract: The switching device includes an electron transport layer; an electron supply layer provided on the electron transport layer and being in contact with the electron transport layer by heterojunction; a source electrode being in contact with the electron supply layer; a drain electrode being in contact with the electron supply layer at a position spaced from the source electrode; and a first gate electrode provided above the electron supply layer, and provided between the source electrode and the drain electrode when viewed in a plan view from above. The first gate electrode is electrically connected above the electron supply layer to the drain electrode. An on-resistance of the switching device is lower than an electric resistance between the first gate electrode and the drain electrode.

Abstract: An electrical power circuit assembly includes a heat sink having a first surface portion and a second surface portion, a power semiconductor module being in thermal contact with the first surface portion of the heat sink for dissipating heat from the power semiconductor module to the heat sink via the first heat sink surface portion, and a capacitor having an axis. The capacitor is arranged with its axis essentially parallel to the second heat sink surface portion and with a circumferential surface portion being in thermal contact with the second surface portion of the heat sink for dissipating heat from the capacitor to the heat sink via the second heat sink surface portion.

Abstract: A semiconductor device comprises an n+ type SiC semiconductor substrate, an n type low concentration drift layer of an SiC semiconductor on the substrate, p type channel regions selectively arranged in the drift layer with a specified distance between the channel regions, an n type source region selectively arranged in the channel region, a source electrode in common contact with the source region and the channel region, and a gate electrode disposed over the drift layer between two channel regions, and over a part of the channel region positioned between the drift layer and the source region intercalating a gate oxide film therebetween. The drift layer has a low concentration of at most 70% of the concentration that is required to exhibit a specified withstand voltage at a minimum ON resistance.

Abstract: In a silicon carbide semiconductor device, a p-type SiC layer is disposed in a corner of a bottom of a trench. Thus, even if an electric field is applied between a drain and a gate when a MOSFET is turned off, a depletion layer in a pn junction between the p-type SiC layer and an n? type drift layer greatly extends toward the n? type drift layer, and a high voltage caused by an influence of a drain voltage hardly enters a gate insulating film. Hence, an electric field concentration within the gate insulating film can be reduced, and the gate insulating film can be restricted from being broken. In this case, although the p-type SiC layer may be in a floating state, the p-type SiC layer is formed in only the corner of the bottom of the trench. Thus, the deterioration of the switching characteristic is relatively low.

Abstract: The present invention provides a substrate structure, a semiconductor device, and a manufacturing method thereof. The substrate structure comprises: a semiconductor substrate; and a first isolation region, wherein the first isolation region comprises: a first trench extending through the semiconductor substrate; and a first dielectric layer filling the first trench. Due to the isolation region extending through the substrate, it is possible to make device structures on both surfaces of the substrate, so as to increase the utilization of the substrate and the integration degree of the devices.

Abstract: An integrated circuit may have an array of memory elements. Each memory element may have multiple memory cells. Each memory element may have a voting circuit that receives signals from the memory cells in that memory element. The voting circuit can produce an output based on the signals. The signals stored by the memory cells of each memory element may be redundant so that the voting circuit can produce an accurate output even in the event that a radiation strike causes some of the memory cells to flip their states to erroneous values. The memory elements may be based on memory cells such as static random-access memory cells and thyristor-based cells.

Abstract: An IGBT module is provided. The IGBT module has at least a first individual IGBT with a first softness during switching-off the IGBT module, and at least a second individual IGBT connected in parallel to the at least one first IGBT. The at least one second individual IGBT has a second softness during switching-off the IGBT module which is different than the first softness. Further a circuit and an electronic power device having two individual IGBTs, which are connected in parallel, are provided.

Abstract: Apparatuses and methods can include write schemes for a thyristor memory cell in which an access pulse applied to the gate of the thyristor memory cell is adjusted relative to the data pulse to write data into the thyristor memory cell. Some of the write schemes may substantially reduce or eliminate an unselected data line disturb. In various embodiments, the thyristor memory cell can be structured with two control nodes and its cathode or anode coupled to a reference voltage node common to all thyristor memory cells in a memory array. Additional apparatuses and methods are disclosed.

Abstract: A 3D semiconductor device and a method of manufacturing the same are provided. The method includes forming a first semiconductor layer including a common source node on a semiconductor substrate, forming a transistor region on the first semiconductor layer, wherein the transistor region includes a horizontal channel region substantially parallel to a surface of the semiconductor substrate, and source and drain regions branched from the horizontal channel region to a direction substantially perpendicular to the surface of the semiconductor substrate, processing the first semiconductor layer to locate the common source node corresponding to the source region, forming a gate in a space between the source region and the drain region, forming heating electrodes on the source region and the drain region, and forming resistance variable material layers on the exposed heating electrodes.

Abstract: A light emitting device includes a double-sided electrode type semiconductor light emitting element that has a first electrode formed on a front side of the double-sided type semiconductor light emitting element and a second electrode formed on a rear side of the double sided type semiconductor light emitting element and is configured to emit light from a side wall surface of the double-sided electrode type semiconductor light emitting element, a first lead frame that is bonded to a whole area of one face of the first electrode, a second lead frame that is bonded to a whole area of one face of the second electrode, and a case in which a portion of the first lead frame and a portion of the second lead frame is embedded.

Abstract: A 3D semiconductor device and a method of manufacturing the same are provided. The method includes forming a first semiconductor layer including a common source node on a semiconductor substrate, forming a transistor region on the first semiconductor layer, wherein the transistor region includes a horizontal channel region substantially parallel to a surface of the semiconductor substrate, and source and drain regions branched from the horizontal channel region to a direction substantially perpendicular to the surface of the semiconductor substrate, processing the first semiconductor layer to locate the common source node corresponding to the source region, forming a gate in a space between the source region and the drain region, forming heating electrodes on the source region and the drain region, and forming resistance variable material layers on the exposed heating electrodes.

Abstract: A bi-directional electrostatic discharge diode structure consumes substantially less silicon real estate and provides ultra-low capacitance by utilizing a p? epitaxial layer that touches and lies between an n+ lower epitaxial layer and an n+ upper epitaxial layer. A metal contact touches and lies over a p+ layer, which touches and lies over the n+ upper epitaxial layer.

Abstract: A power semiconductor device includes a first layer of a first conductivity type, which has a first main side and a second main side opposite the first main side. A second layer of a second conductivity type is arranged in a central region of the first main side and a fourth electrically conductive layer is arranged on the second layer. On the second main side a third layer with a first zone of the first conductivity type with a higher doping than the first layer is arranged followed by a fifth electrically conductive layer. The area between the second layer and the first zone defines an active area. The third layer includes at least one second zone of the second conductivity type, which is arranged in the same plane as the first zone. A sixth layer of the first conductivity type with a doping, which is lower than that of the first zone and higher that that of the first layer, is arranged between the at least one second zone and the first layer.

Abstract: An improved gated thyristor that utilizes less silicon area than IGBT, BIPOLARs or MOSFETs sized for the same application is provided. Embodiments of the inventive thyristor have a lower gate charge, and a lower forward drop for a given current density. Embodiments of the thyristor once triggered have a latch structure that does not have the same Cgd or Ccb capacitor that must be charged from the gate, and therefore the gated thyristor is cheaper to produce, and requires a smaller gate driver, and takes up less space than standard solutions. Embodiments of the inventive thyristor provide a faster turn off speed than the typical >600 ns using a modified MCT structure which results in the improved tail current turn off profile (<250 ns). Additionally, series resistance of the device is reduced without comprising voltage blocking ability is achieved. Finally, a positive only gate drive means is taught as is a method to module the saturation current using the gate terminal.

Abstract: A protective device for a voltage-controlled semiconductor switch has a gate connection, a power emitter connection, an auxiliary emitter connection and a collector connection. The semiconductor switch can switch a current between the collector connection and the power emitter connection. A voltage-limiting device limits the voltage between the gate connection and the power emitter connection. A deactivation device is connected to the voltage-limiting device and deactivates the voltage-limiting device during a switch-on of the semiconductor switch.

Abstract: In a non-punch-through (NPT) insulated gate bipolar transistor (IGBT), a rear surface structure including a p+ collector layer and a collector electrode is provided on a rear surface of an n? semiconductor substrate and a depletion layer which is spread from a pn junction between a p base region and an n? drift layer when the NPT-IGBT is turned off does not come into contact with the p+ collector layer. A carrier concentration of a region of the n? drift layer that is provided at a depth of 0.3 ?m or less from a pn junction between the n? drift layer and the p+ collector layer is in the range of 30% to 70% of a stored carrier concentration of a region of the n? drift layer that is provided at a depth greater than 0.3 ?m from the pn junction.

Abstract: A semiconductor device includes an IGBT forming region and a diode forming region. The IGBT forming region includes an IGBT operating section that operates as an IGBT and a thinned-out section that does not operate as an IGBT. The IGBT operating section includes a channel region, and the thinned-out section includes a first anode region. The diode forming region includes a second anode region. When an area density is defined as a value calculated by integrating a concentration profile of second conductivity type impurities in each of the channel region, the first anode region, and the second anode region in a depth direction, an area density of the channel region is higher than an area density of the first anode region and an area density of the second anode region.

Abstract: A semiconductor structure comprising a semiconductor unit, a first conductive structure, a first conductive plug, and a second conductive structure is provided. The semiconductor unit has a substrate on a first side of the semiconductor unit. The substrate has at least a hole. The first conductive plug is in the hole and the hole may be full of the conductive plug. The first conductive structure is on the surface of the semiconductor unit. The surface is at the first side of the semiconductor unit. The second conductive structure is on a surface at a second side of the substrate of the semiconductor unit.

Abstract: An insulated gate turn-off thyristor has a layered structure including a p+ layer (e.g., a substrate), an n? layer, a p-well, vertical insulated gate regions formed in the p-well, and n+ regions between the gate regions, so that vertical NPN and PNP transistors are formed. Some of the gate regions are first gate regions that only extend into the p-well, and other ones of the gate regions are second gate regions that extend through the p-well and into the n? layer to create a vertical conducting channel when biased. The second gate regions increase the beta of the PNP transistor. When the first gate regions are biased, the base of the NPN transistor is narrowed to increase its beta. When the product of the betas exceeds one, controlled latch-up of the thyristor is initiated. The distributed second gate regions lower the minimum gate voltage needed to turn on the thyristor.

Abstract: A modified MOSFET structure comprises an integrated field effect rectifier connected between the source and drain of the MOSFET to shunt current during switching of the MOSFET. The integrated FER provides faster switching of the MOSFET due to the absence of injected carriers during switching while also decreasing the level of EMI relative to discrete solutions. The integrated structure of the MOSFET and FER can be fabricated using N-, multi-epitaxial and supertrench technologies, including 0.25 ?m technology. Self-aligned processing can be used.

Abstract: A semiconductor device includes a semiconductor substrate, a first p-channel laterally diffused metal oxide semiconductor (LDMOS) transistor formed over the semiconductor substrate and additional p-channel LDMOS transistors formed over the semiconductor substrate. First drain and gate electrodes are formed over the substrate and are coupled to the first LDMOS transistor. Additional drain and gate electrodes are formed over the substrate and are coupled to the second LDMOS transistor. A common source electrode for the first and second LDMOS transistors is also formed over the substrate.

Abstract: A semiconductor switch comprises a PNPN structure arranged to provide an SCR-like functionality, and a MOS gate structure, preferably integrated on a common substrate. The switch includes ohmic contacts for the MOS gate, and for the cathode and gate regions of the PNPN structure; the anode contact is intrinsic. A fixed voltage is typically applied to an external node. The MOS gate structure allows current to be conducted between the external node and the intrinsic anode when on, and the PNPN structure conducts the current from the anode to the cathode when an appropriate voltage is applied to the gate contact. Regenerative feedback keeps the switch on once it begins to conduct. The MOS gate inhibits the flow of current between the external node and anode—and thereby turns off the switch—when off. When on, the MOS gate's channel resistance serves as a ballast resistor.

Abstract: A device includes a first thyristor element configured to be coupled to a first voltage line and a second voltage line, wherein the first voltage line is configured to transmit power in a first phase and the second voltage line is configured to transmit power in a second phase. The device includes a second thyristor element configured to be coupled to the second voltage line and a third voltage line, wherein the third voltage line is configured to transmit power in a third phase. The device includes a third thyristor element configured to be coupled to the first voltage line and the third voltage line.

Abstract: The present invention relates to a manufacturing method of SOI devices, and in particular, to a manufacturing method of SOI high-voltage power devices.

Abstract: A semiconductor arrangement includes a circuit carrier, bonding wire and at least N half bridge circuits. The circuit carrier includes a first metallization layer, a second metallization layer, an intermediate metallization layer arranged between the first metallization layer and the second metallization layer, a first insulation layer arranged between the intermediate metallization layer and the second metallization layer, and a second insulation layer arranged between the first metallization layer and the intermediate metallization layer. Each half bridge circuit includes a controllable first semiconductor switch and a controllable second semiconductor switch. The first semiconductor switch and the second semiconductor switch of each half bridge circuit are arranged on that side of the first metallization layer of the circuit carrier facing away from the second insulation layer. The bonding wire is directly bonded to the intermediate metallization layer of the circuit carrier at a first bonding location.

Abstract: A rectifier building block has four electrodes: source, drain, gate and probe. The main current flows between the source and drain electrodes. The gate voltage controls the conductivity of a narrow channel under a MOS gate and can switch the RBB between OFF and ON states. Used in pairs, the RBB can be configured as a three terminal half-bridge rectifier which exhibits better than ideal diode performance, similar to synchronous rectifiers but without the need for control circuits. N-type and P-type pairs can be configured as a full bridge rectifier. Other combinations are possible to create a variety of devices.

Abstract: A method of manufacturing a SOI high voltage power chip with trenches is disclosed. The method comprises: forming a cave and trenches at a SOI substrate; filling oxide in the cave; oxidizing the trenches, forming oxide isolation regions for separating low voltage devices at the same time; filling oxide in the oxidized trenches; and then forming drain regions, source regions and gate regions for a high voltage power device and low voltage devices. The process involves depositing an oxide layer overlapping the cave of the SOI substrate. A SOI high voltage power chip thus made will withstand at least above 700V voltage.

Abstract: The invention is related to a semiconductor device with alternately arranged P-type and N-type thin semiconductor layers and method for manufacturing the same. For P-type device, the method includes trench formation, thermal oxide formation on trench sidewalls, N-type silicon formation in trenches, N-type impurity diffusion through thermal oxide into P-type epitaxial layer, oxidation of N-type silicon in trenches and oxide removal. In the semiconductor device, N-type thin semiconductor layers are formed by N-type impurity diffusion through oxide to P-type epitaxial layers, and trenches are filled with oxide. With this method, relatively low concentration impurity in high voltage device can be realized by current mass production process, and the device development cost and manufacturing cost are decreased.

Abstract: An Adjustable Field Effect Rectifier uses aspects of MOSFET structure together with an adjustment pocket or region to result in a device that functions reliably and efficiently at high voltages without significant negative resistance, while also permitting fast recovery and operation at high frequency without large electromagnetic interference.

Abstract: Disclosed is a method for controlling the recombination rate in the base region of a bipolar semiconductor component, and a bipolar semiconductor component.

Abstract: To provide a semiconductor device in which dielectric breakdown strength in a peripheral region is increased without increasing on-resistance. An IGBT comprises a body region, guard ring, and collector layer. The body region is formed within an active region in a surface layer of a drift layer. The guard ring is formed within a peripheral region in the surface layer of the drift layer, and surrounds the body region. The collector layer is formed at a back surface side of the drift layer, and is formed across the active region and the peripheral region. A distance F between a back surface of the guard ring and the back surface of the drift layer is greater than a distance between a back surface of the body region and the back surface of the drift layer. A thickness H of the collector layer in the peripheral region is smaller than a thickness D of the collector layer in the active region.

Abstract: Double gate IGBT having both gates referred to a cathode in which a second gate is for controlling flow of hole current. In on-state, hole current can be largely suppressed. While during switching, hole current is allowed to flow through a second channel. Incorporating a depletion-mode p-channel MOSFET having a pre-formed hole channel that is turned ON when 0V or positive voltages below a specified threshold voltage are applied between second gate and cathode, negative voltages to the gate of p-channel are not used. Providing active control of holes amount that is collected in on-state by lowering base transport factor through increasing doping and width of n well or by reducing injection efficiency through decreasing doping of deep p well. Device includes at least anode, cathode, semiconductor substrate, n? drift region, first & second gates, n+ cathode region; p+ cathode short, deep p well, n well, and pre-formed hole channel.

Abstract: A method for manufacturing a semiconductor device according to the present invention has a step of forming a plurality of MOSFETs each having a channel of a first conductivity type in a stripe on the first major surface of a wafer; a step of implanting an impurity of a first conductivity type into the second major surface of the wafer, and performing a laser annealing treatment in a stripe leaving equidistant gaps, to form a buffer layer that has been activated in a stripe; a step of implanting an impurity of a second conductivity type into the second major surface of the substrate after forming the buffer layer, and performing a laser annealing treatment on the entire surface of the second major surface, to form a collector layer, and to activate the buffer layer; and a step of forming an emitter electrode on the first major surface, and forming a collector electrode on the second major surface.

Abstract: A gate turn-off thyristor (GTO) device has a lower portion, an upper portion and a lid. The lower portion has a lower base region of a first conductivity type, and a lower emitter region of a second conductivity type disposed at or from a lower surface of the lower base region. A lower junction is formed between the lower base region and the lower emitter region. The upper portion has an upper base region of the second conductivity type, and upper emitter regions of the first conductivity type disposed at or from an upper surface of the upper base region. An upper-lower junction is formed between the lower base region and the upper base region, and upper junctions are formed between the upper base region and the upper emitter regions. The upper base region and upper emitter regions form an upper base surface with first conductive contacts to the upper base region alternating with second conductive contacts to the upper emitter regions. The lid has a layer of insulator with upper and lower surfaces.

Abstract: In a base region of a first conductivity type, at least one emitter region of a second conductivity type and at least one sense region of the second conductivity type, spaced away from the emitter region, are selectively formed. The emitter region and the sense region are located so as to be aligned in a second direction perpendicular to a first direction going from a collector region of the first conductivity type, which is formed so as to be spaced away from the base region, toward the base region. The width of the sense region, the width of the emitter region, the width of a part of the base region that is adjacent to the sense region, and the width of a part of the base region that is adjacent to the emitter region in the second direction are set in such a manner that a sense ratio varies in a desired manner in accordance with variation in collector current.

Abstract: An insulated gate type thyristor includes: a first current terminal semiconductor region of a first conductivity type having a high impurity concentration; a first base semiconductor region of a second conductivity type opposite to the first conductivity type having a low impurity concentration and formed on the first current terminal semiconductor region; a second base semiconductor region of the first conductivity type having a low impurity concentration and formed on the first base semiconductor region; a second current terminal semiconductor region of the second conductivity type having a high impurity concentration and formed on the second base semiconductor region; a trench passing through the second current terminal semiconductor region and entering the second base semiconductor region leaving some depth thereof, along a direction from a surface of the second current terminal semiconductor region toward the first base semiconductor region; and an insulated gate electrode structure formed in the trench.

Abstract: A gate turn-off thyristor (GTO) device has a lower portion, an upper portion and a lid. The lower portion has a lower base region of a first conductivity type, and a lower emitter region of a second conductivity type disposed at or from a lower surface of the lower base region. A lower junction is formed between the lower base region and the lower emitter region. The upper portion has an upper base region of the second conductivity type, and upper emitter regions of the first conductivity type disposed at or from an upper surface of the upper base region. An upper-lower junction is formed between the lower base region and the upper base region, and upper junctions are formed between the upper base region and the upper emitter regions. The upper base region and upper emitter regions form an upper base surface with first conductive contacts to the upper base region alternating with second conductive contacts to the upper emitter regions. The lid has a layer of insulator with upper and lower surfaces.

Abstract: In a chip containing high-voltage device with a semiconductor substrate of a first conductivity type, a method of implementing low-voltage power supply is provided, wherein the electrical potential of an isolated region of a second conductivity type in a surface portion is used as one output terminal or as a voltage by which a transistor is controlled to provide output current for a low-voltage power supply. The other output terminal could be either terminal of the two that apply high voltage to high-voltage device or could be a floating terminal. Using this method, a low-voltage power supply can be implemented not only for the low-voltage integrated circuit (I) in a power IC containing one high-voltage device, but also for the low-voltage integrated circuit in a power IC having totem-pole connection or CMOS connection. As there is no need to implement depletion mode device in the chip, the fabrication cost is reduced.

Abstract: The present invention alters the frequency response of an optoelectronic device to match a driver circuit that drives the optoelectronic device. The optoelectronic device is formed on a first substrate. A matching circuit is also formed on the first substrate and coupled to the optoelectronic device to change its frequency response. The matching circuit provides a precise and repeatable amount of inductance to an optoelectronic device.

Abstract: Double gate IGBT having both gates referred to a cathode in which a second gate is for controlling flow of hole current. In on-state, hole current can be largely suppressed. While during switching, hole current is allowed to flow through a second channel. Incorporating a depletion-mode p-channel MOSFET having a pre-formed hole channel that is turned ON when 0V or positive voltages below a specified threshold voltage are applied between second gate and cathode, negative voltages to the gate of p-channel are not used. Providing active control of holes amount that is collected in on-state by lowering base transport factor through increasing doping and width of n well or by reducing injection efficiency through decreasing doping of deep p well. Device includes at least anode, cathode, semiconductor substrate, n? drift region, first & second gates, n+ cathode region; p+ cathode short, deep p well, n well, and pre-formed hole channel.

Abstract: A semiconductor switch comprises a PNPN structure arranged to provide an SCR-like functionality, and a MOS gate structure, preferably integrated on a common substrate. The switch includes ohmic contacts for the MOS gate, and for the cathode and gate regions of the PNPN structure; the anode contact is intrinsic. A fixed voltage is typically applied to an external node. The MOS gate structure allows current to be conducted between the external node and the intrinsic anode when on, and the PNPN structure conducts the current from the anode to the cathode when an appropriate voltage is applied to the gate contact. Regenerative feedback keeps the switch on once it begins to conduct. The MOS gate inhibits the flow of current between the external node and anode—and thereby turns off the switch—when off. When on, the MOS gate's channel resistance serves as a ballast resistor.

Abstract: A process for forming a conductive gate structure for a sub-0.25 MOSFET technology, has been developed. The process features a conductive gate structure defined from a composite polysilicon or amorphous layer, which in turn is obtained via a dual deposition procedure. The first, or underlying silicon layer of the composite silicon layer, is deposited using a first silane flow rate which results in a silicon layer offering good performance characteristics but comprised with large silicon bumps. The second or overlying silicon layer of the composite silicon layer, is next deposited using a second silane flow rate, with the second silane flow greater than the silane flow used for the underlying silicon layer. The second silicon layer is formed with silicon bumps smaller in size than the silicon bumps of the first silicon layer.