Abstract: A semiconductor device includes a plurality of floating regions, an insulating layer and a capacitance forming portion. The plurality of floating regions are arranged on a surface of a semiconductor substrate in a row, wherein the plurality of floating regions are provided with insulating regions therebetween. The plurality of floating regions include a first floating region and a second floating region. The second floating region is located farther than the first floating region from an island region of a predetermined potential on the semiconductor substrate. The insulating layer is interposed between each of the plurality of floating regions and a semiconductor material layer of the semiconductor substrate. The capacitance forming portion forms an external capacitance in parallel with the capacitance of the insulating region between the first floating region and the island region of the predetermined potential.

Abstract: A semiconductor device has a cell field with drift zones of a first type of conductivity and charge carrier compensation zones of a second type of conductivity complementary to the first type. An edge region which surrounds the cell field has a higher blocking strength than the cell field, the edge region having a near-surface area which is undoped to more weakly doped than the drift zones, and beneath the near-surface area at least one buried, vertically extending complementarily doped zone is positioned.

Abstract: A voltage-switchable dielectric layer may be employed on a die for electrostatic discharge (ESD) protection. The voltage-switchable dielectric layer functions as a dielectric layer between terminals of the die during normal operation of the die. When ESD events occur at the terminals of the die, a high voltage between the terminals switches the voltage-switchable dielectric layer into a conducting layer to allow current to discharge to a ground terminal of the die without the current passing through circuitry of the die. Thus, damage to the circuitry of the die is reduced or prevented during ESD events on dies with the voltage-switchable dielectric layer. The voltage-switchable dielectric layer may be deposited on the back side of a die for protection during stacking with a second die to form a stacked IC. A method includes depositing a voltage-switchable dielectric layer on a first die between a first terminal and a second terminal.

Abstract: A voltage-switchable dielectric layer may be employed on a die for electrostatic discharge (ESD) protection. The voltage-switchable dielectric layer functions as a dielectric layer between terminals of the die during normal operation of the die. When ESD events occur at the terminals of the die, a high voltage between the terminals switches the voltage-switchable dielectric layer into a conducting layer to allow current to discharge to a ground terminal of the die without the current passing through circuitry of the die. Thus, damage to the circuitry of the die is reduced or prevented during ESD events on dies with the voltage-switchable dielectric layer. The voltage-switchable dielectric layer may be deposited on the back side of a die for protection during stacking with a second die to form a stacked IC.

Abstract: A wide-band-gap reverse-blocking MOS-type semiconductor device includes a SiC n?-type drift layer; a p+-type substrate on the first major surface side of the drift layer; a trench extending through a p+-type substrate into the drift layer; a titanium electrode in the trench bottom that forms a Schottky junction with the SiC n?-type drift layer; an active section including a MOS-gate structure on the second major surface side of the drift layer facing to the area, in which the Schottky junctions are formed; a breakdown withstanding section surrounding the active section; and a trench isolation layer surrounding the breakdown withstanding section, the trench isolation layer extending from the second major surface of the drift layer into p+-type substrate and including insulator film buried therein. The device facilitates making a high current flow with a low ON-voltage and exhibits a very reliable reverse blocking capability.

Abstract: A multi-trench termination structure for semiconductor device is disclosed, where the semiconductor device includes a semiconductor substrate and an active structure region. The multi-trench termination structure includes multiple trenches defined on an exposed face of the semiconductor substrate, a first mask layer formed on a partial exposed surface of the semiconductor substrate and corresponding to a termination structure region of the semiconductor device, a gate insulation layer formed in the trenches, a conductive layer formed on the gate insulation layer and protruding out of the exposed surface of the semiconductor substrate, and a metal layer formed over the first mask layer and conductive layer on the termination structure region of the semiconductor device.

Abstract: A superjunction device and methods for layout design and fabrication of a superjunction device are disclosed. A layout of active cell column structures can be configured so that a charge due to first conductivity type dopants balances out charge due to second conductivity type dopants in a doped layer in an active cell region. A layout of end portions of the active cell column structures proximate termination column structures can be configured so that a charge due to the first conductivity type dopants in the end portions and a charge due to the first conductivity type dopants in the termination column structures balances out charge due to the second conductivity type dopants in a portion of the doped layer between the termination column structures and the end portions.

Abstract: An integrated circuit is disclosed having a semiconductor component comprising a first p-type region and a first n-type region adjoining the first p-type region, which together form a first pn junction having a breakdown voltage. A further n-type region adjoining the first p-type region or a further p-type region adjoining the first n-type region is provided, the first p-type or n-type region and the further n-type or p-type region adjoining the latter together forming a further pn junction having a further breakdown voltage, the first pn junction and the further pn junction being connected or connectable to one another in such a way that, in the case of an overloading of the semiconductor component, on account of a current loading of the first pn junction, first of all the further pn junction breaks down.

Abstract: A semiconductor device includes a semiconductor substrate of a first electroconductive type, a first principal electrode arranged on a first side of the semiconductor substrate, a first semiconductor layer of a second electroconductive type arranged on a second side of the semiconductor substrate and at a certain distance from an edge of the semiconductor substrate, plural second semiconductor layer portions of the second electroconductive type arranged on the second side of the semiconductor substrate and positioned selectively in between the edge and the first semiconductor layer, an insulating film arranged to cover a portion of the first semiconductor layer from the edge, an electroconductive film arranged to cover portions of the insulating film and the first semiconductor layer, and a second principal electrode arranged in contact with the first semiconductor layer and the electroconductive film.

Abstract: Channel regions continuous with transistor cells are disposed also below a gate pad electrode. The channel region below the gate pad electrode is fixed to a source potential. Thus, a predetermined reverse breakdown voltage between a drain and a source is secured without forming a p+ type impurity region below the entire lower surface of the gate pad electrode. Furthermore, a protection diode is formed in a conductive layer disposed at the outer periphery of an operation region.

Abstract: A power semiconductor device has semiconductor layers, including: first layer of first type; second and third layers respectively of first and second types alternately on the first layer; fourth layers of second type on the third layers; fifth layers of first type on the fourth layer; sixth and seventh layers respectively of second and first types alternately on the second and third layers; a first electrode connected to the first layer; an insulation film on fourth, sixth, and seventh layers; a second electrode on fourth, sixth, and seventh layers via the insulation film; and a third electrode joined to fourth and fifth layers, wherein the sixth layers are connected to the fourth layers and one of the third layers between two fourth layers, and an impurity concentration of the third layers below the sixth layers is higher than that of the third layers under the fourth layers.

Abstract: A double-gate semiconductor device includes a MOS gate and a junction gate, in which the bias of the junction gate is a function of the gate voltage of the MOS gate. The breakdown voltage of the double-gate semiconductor device is the sum of the breakdown voltages of the MOS gate and the junction gate. The double-gate semiconductor device provides improved RF capability in addition to operability at higher power levels as compared to conventional transistor devices. The double-gate semiconductor device may also be fabricated in a higher spatial density configuration such that a common implantation between the MOS gate and the junction gate is eliminated.

Abstract: A semiconductor device comprises a semiconductor layer, a body region of a first conductivity type formed in the semiconductor layer and extending from a first surface of the semiconductor layer, a first region of a second conductivity type formed in the body region, and a second region of the first conductivity type formed in the body region. The first region extends from the first surface of the semiconductor layer and provides a current electrode region of the semiconductor device. The second region surrounds the first region. The doping concentration of the first conductivity type in the second region is greater than a doping concentration of the first conductivity type in the body region.

Abstract: A master having a substrate including displaying units and an ESD protection structure including an adjacent first region and a second region is provided. The displaying units have a predetermined-cutting region therebetween. Each displaying unit includes a peripheral circuit region and a display region having pixels.

Abstract: A wide bandgap silicon carbide device has an avalanche control structure formed in an epitaxial layer of a first conductivity type above a substrate that is connected to a first electrode of the device. A first region of a second conductivity type is in the upper surface of the epitaxial layer with a connection to a second electrode of the device. A second region of the first conductivity type lies below the first region and has a dopant concentration greater than the dopant concentration in the epitaxial layer.

Abstract: A semiconductor component includes a semiconductor body having a first side, a second side, an edge delimiting the semiconductor body in a lateral direction, an inner region and an edge region. A first semiconductor zone of a first conduction type is arranged in the inner region and in the edge region. A second semiconductor zone of a second conduction type is arranged in the inner region and adjacent to the first semiconductor zone. A trench is arranged in the edge region and has first and second sidewalls and a bottom, and extends into the semiconductor body. A doped first sidewall zone of the second conduction type is adjacent to the first sidewall of the trench. A doped second sidewall zone of the second conduction type is adjacent to the second sidewall of the trench. A doped bottom zone of the second conduction type is adjacent to the bottom of the trench. Doping concentrations of the sidewall zones are lower than a doping concentration of the bottom zone.

Abstract: A method for fabricating a semiconductor device is provided. According to this method, a first gate electrode and a second gate electrode are formed overlying a first portion of a silicon substrate, and ions of a first conductivity-type are implanted into a second portion of the silicon substrate to define a first conductivity-type diode region within the silicon substrate. Ions of a second conductivity-type are implanted into a third portion of the silicon substrate to define a second conductivity-type diode region within the silicon substrate. During one of the steps of implanting ions of the first conductivity-type and implanting ions of the second conductivity-type, ions are also implanted into at least part of the first portion to define a separation region within the first portion. The separation region splits the first portion into a first well device region and a second well device region. The separation region is formed in series between the first well device region and the second well device region.

Abstract: A superjunction device and methods for layout design and fabrication of a superjunction device are disclosed. A layout of active cell column structures can be configured so that a charge due to first conductivity type dopants balances out charge due to second conductivity type dopants in a doped layer in an active cell region. A layout of end portions of the active cell column structures proximate termination column structures can be configured so that a charge due to the first conductivity type dopants in the end portions and a charge due to the first conductivity type dopants in the termination column structures balances out charge due to the second conductivity type dopants in a portion of the doped layer between the termination column structures and the end portions.

Abstract: A Schottky diode structure with low reverse leakage current and low forward voltage drop has a first conductive material semiconductor substrate combined with a metal layer. An oxide layer is formed around the edge of the combined conductive material semiconductor substrate and the metal layer. A plurality of dot-shaped or line-shaped second conductive material regions are formed on the surface of the first conductive material semiconductor substrate connecting to the metal layer. The second conductive material regions form depletion regions in the first conductive material semiconductor substrate. The depletion regions can reduce the leakage current area of the Schottky diode, thereby reducing the reverse leakage current and the forward voltage drop. When the first conductive material is a P-type semiconductor, the second conductive material is an N-type semiconductor. When the first conductive material is an N-type semiconductor, the second conductive material is a P-type semiconductor.

Abstract: The invention relates to an integrated circuit having a semiconductor component (10) comprising a first p-type region (12) and a first n-type region (11) adjoining the first p-type region (12), which together form a first pn junction having a breakdown voltage. According to the invention, a further n-type region adjoining the first p-type region or a further p-type region (13) adjoining the first n-type region (11) is provided, the first p-type or n-type region (11) and the further n-type or p-type region (13) adjoining the latter together forming a further pn junction having a further breakdown voltage, the first pn junction and the further pn junction being connected or connectable to one another in such a way that, in the case of an overloading of the semiconductor component, on account of a current loading of the first pn junction, first of all the further pn junction breaks down.

Abstract: A semiconductor device has a silicon substrate, an external connection terminal disposed on the silicon substrate, an internal circuit region disposed on the silicon substrate, an NMOS transistor for electrostatic discharge protection provided between the external connection terminal and the internal circuit region, and a wiring connecting together the external connection terminal and the NMOS transistor and connecting together the NMOS transistor and the internal circuit region. The NMOS transistor has a drain region and a gate electrode whose potential is fixed to a ground potential. The external connection terminal is smaller than the drain region and is formed above the drain region.

Abstract: Provided is a semiconductor device including an electrostatic discharge (ESD) protection element provided between an external connection terminal and an internal circuit region. In the semiconductor device, interconnect extending from the external connection terminal to the ESD protection element includes a plurality of metal interconnect layers so that a resistance of the interconnect extending from the external connection terminal to the ESD protection element is made smaller than a resistance of interconnect extending from the ESD protection element to an internal element. The interconnect extending from the ESD protection element to the internal element includes metal interconnect layers equal to or smaller in number than the plurality of interconnect layers used in the interconnect extending from the external connection terminal to the ESD protection element.

Abstract: A double-gate semiconductor device provides a high breakdown voltage allowing for a large excursion of the output voltage that is useful for power applications. The double-gate semiconductor device may be considered a double-gate device including a MOS gate and a junction gate, in which the bias of the junction gate may be a function of the gate voltage of the MOS gate. The breakdown voltage of the double-gate semiconductor device is the sum of the breakdown voltages of the MOS gate and the junction gate. Because an individual junction gate has an intrinsically high breakdown voltage, the breakdown voltage of the double-gate semiconductor device is greater than the breakdown voltage of an individual MOS gate. The double-gate semiconductor device provides improved RF capability in addition to operability at higher power levels as compared to conventional transistor devices.

Abstract: An ESD protecting circuit and a manufacturing method thereof are provided. The ESD protecting circuit includes a device isolation layer, first and second high-concentration impurity regions, a third high-concentration impurity region of a complementary type, first and second conductive wells, and a fourth conductive impurity region. The ESD protecting circuit is configured as a field transistor without a gate electrode, and the high breakdown voltage characteristics of the field transistor are lowered by implanting impurity ions, providing an ESD protecting circuit with a low breakdown voltage and low leakage current. Because the leakage current is reduced, the ESD protecting circuit can be used for an analog I/O device that is sensitive to current fluxes. Also, an N-type well may protect a junction of the field transistor.

Abstract: A vertical transient voltage suppressing (TVS) device includes a semiconductor substrate of a first conductivity type where the substrate is heavily doped, an epitaxial layer of the first conductivity type formed on the substrate where the epitaxial layer has a first thickness, and a base region of a second conductivity type formed in the epitaxial layer where the base region is positioned in a middle region of the epitaxial layer. The base region and the epitaxial layer provide a substantially symmetrical vertical doping profile on both sides of the base region. In one embodiment, the base region is formed by high energy implantation. In another embodiment, the base region is formed as a buried layer. The doping concentrations of the epitaxial layer and the base region are selected to configure the TVS device as a punchthrough diode based TVS or an avalanche mode TVS.

Abstract: Channel regions continuous with transistor cells are disposed also below a gate pad electrode. The channel region below the gate pad electrode is fixed to a source potential. Thus, a predetermined reverse breakdown voltage between a drain and a source is secured without forming a p+ type impurity region below the entire lower surface of the gate pad electrode. Furthermore, a protection diode is formed in a conductive layer disposed at the outer periphery of an operation region.

Abstract: A semiconductor power device supported on a semiconductor substrate includes an electrostatic discharge (ESD) protection circuit disposed on a first portion of patterned ESD polysilicon layer on top of the semiconductor substrate. The semiconductor power device further includes a second portion of the patterned ESD polysilicon layer constituting a body implant ion block layer for blocking implanting body ions to enter into the semiconductor substrate below the body implant ion block layer. In an exemplary embodiment, the electrostatic discharge (ESD) polysilicon layer on top of the semiconductor substrate further covering a scribe line on an edge of the semiconductor device whereby a passivation layer is no longer required manufacturing the semiconductor device for reducing a mask required for patterning the passivation layer.

Abstract: An integrated circuit includes a first electrode and a first resistivity changing material coupled to the first electrode. The first resistivity changing material has a planarized surface. The integrated circuit includes a second resistivity changing material contacting the planarized surface of the first resistivity changing material and a second electrode coupled to the second resistivity changing material. A cross-sectional width of the first resistivity changing material is less than a cross-sectional width of the second resistivity changing material.

Abstract: An active device array substrate including a substrate, a plurality of pixel units, a plurality of first conductive lines, a plurality of second conductive lines, a lead line, at least one first electrostatic discharge protection circuit, and at least one second electrostatic discharge protection circuit is provided. The pixel units are arranged on the substrate. Additionally, the first conductive lines and the second conductive lines are disposed on the substrate and electrically connected to the pixel units respectively. Moreover, the lead line crosses the first conductive lines. The first electrostatic discharge protection circuit is disposed at one side of the lead line, and the second electrostatic discharge protection circuit corresponding to the first electrostatic discharge protection circuit is disposed at the other side of the lead line.

Abstract: A semiconductor device includes a substrate and a memory cell formed on the substrate. The memory cell includes a word line. The semiconductor device also includes a protection area formed in the substrate, a conductive structure configured to extend the word line to the protection area, and a contact configured to short the word line and the protection area.

Abstract: A protection circuit protects a semiconductor device provided on a semiconductor substrate and including an interconnect from charge entering the interconnect during fabrication of the semiconductor device. The protection circuit includes a first metal interconnect connected to the interconnect; a forward diode and a backward diode connected in parallel to the interconnect; an NMIS whose drain is connected to the output port of the forward diode, whose source is connected to the semiconductor substrate and whose gate is grounded through an upper metal interconnect; a PMIS whose drain is connected to the input port of the backward diode and whose source is connected to the semiconductor substrate; a first antenna connected to the gate of the NMIS; and a second antenna connected to the gate of the PMIS.

Abstract: The invention relates to a semiconductor component comprising a buried temporarily n-doped area (9), which is effective only in the event of turn-off from the conducting to the blocking state of the semiconductor component and prevents chopping of the tail current in order thus to improve the turn-off softness. Said temporarily effective area is created by implantation of K centers (10).

Abstract: Channel regions and gate electrodes are also disposed continuously with transistor cells below a gate pad electrode. The transistor cells are formed in a stripe pattern and allowed to contact a source electrode. In this way, the channel regions and the gate electrodes, which are positioned below the gate pad electrode, are kept at a predetermined potential. Thus, a predetermined drain-source reverse breakdown voltage can be secured without providing a p+ type impurity region on the entire surface below the gate pad electrode.

Abstract: Wiring is routed to assure insulation between wiring traces in a semiconductor integrated circuit device. The device includes a first wiring trace to which a prescribed voltage is supplied; a second wiring trace that takes on a voltage that exceeds the prescribed voltage; and a third wiring trace that only takes on a voltage less than the prescribed voltage. Alternatively, the device includes a first wiring trace to which a prescribed voltage is supplied; a second wiring trace that takes on a voltage less than the prescribed voltage; and a third wiring trace that takes on a voltage equal to or greater than the prescribed voltage. The wiring traces are routed at a certain wiring space in such a manner that the first wiring trace is interposed between the second and third wiring traces. The first wiring trace for which the potential difference is known to be small beforehand is routed so as to always be adjacent to the second wiring trace.

Abstract: A high-voltage termination structure includes a peripheral voltage-spreading network. One or more trench structures are connected at least partly in series between first and second power supply voltages. The trench structures include first and second current-limiting structures connected in series with a semiconductor material, and also includes permanent charge in a trench-wall dielectric. The current-limiting structures in the trench structures are jointly connected in a series-parallel ladder configuration. The current-limiting structures, in combination with the semiconductor material, provide a voltage distribution between the core portion and the edge portion.

Abstract: A semiconductor device with a charge carrier compensation structure in a semiconductor body and to a method for its production. The semiconductor body includes drift zones of a first conduction type and charge compensation zones of a second conduction type complementing the first conduction type. The drift zones include a semiconductor material applied in epitaxial growth zones, wherein the epitaxial growth zones include an epitaxially grown semiconductor material which is non-doped to lightly doped. Towards the substrate, the epitaxial growth zones are provided with a first conduction type incorporated by ion implantation over the entire surface and with selectively introduced doping material zones of a second, complementary conduction type. Towards the front side, the epitaxial growth zones are provided with a second, complementary conduction type incorporated by ion implantation over the entire surface and with selectively introduced doping material zones of the first conduction type.

Abstract: Provided is a semiconductor wafer with a scribe line region and a plurality of element forming regions partitioned by the scribe line region, the semiconductor wafer including: conductive patterns formed in the scribe line region; and an island-shaped passivation film formed above at least a conductive pattern, which is or may be exposed to a side surface of a semiconductor chip obtained by dicing the semiconductor wafer along the scribe line region, among the conductive patterns, so that the island-shaped passivation film is opposed to the conductive pattern.

Abstract: A semiconductor device structure is provided. By placing an insulating dielectric material in the drift region of a device to modulate the electric field distribution and current flow in the drift region, the breakdown voltage of the device is increased while the turn-on impedance of the device is reduced.

Abstract: It is described an Electro Static Discharge protection, wherein diodes are arranged on two electric paths both extending in between two conductors which are connected with input terminals of an ESD sensitive electronic component. Each path comprises two diodes arranged in series and with opposite polarity with respect to each other. At least one of the totally four diodes comprises a different reverse breakdown voltage. The protection circuit is formed integrally with the ESD sensitive electronic component. Due to the serial connection of two diodes in each path the corresponding ESD protection circuit comprises an extremely low capacitance.

Abstract: A method of manufacturing a semiconductor device having an active region and a termination region includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate has an active region and a termination region surrounding the active region. The first main surface is oxidized. A first plurality of trenches and a first plurality of mesas are formed in the termination region. The first plurality of trenches in the termination region are filled with a dielectric material. A second plurality of trenches in the termination region. The second plurality of trenches are with the dielectric material.

Abstract: A semiconductor layer provided on a BOX (buried oxide) layer includes a first P-type region, an N+-type region, and an N?-type region which together form a diode. A plurality of second P-type regions are provided on a bottom part of the semiconductor layer. A plurality of insulating oxide films are interposed between the plurality of second P-type regions. When the diode is in a reverse-biased state, the second P-type region directly below the N+-type region is approximately the same in potential as the N+-type region. The second P-type region will be lower in potential relative to this second P-type region directly below the N+-type region, as the second P-type region gets nearer to the first P-type region. Electric field concentration can thus be relaxed at an interface between the semiconductor layer and the BOX layer, whereby improvement in breakdown voltage of the diode is realized.

Abstract: The present invention provides a system comprising a semiconductor device, a method of controlling the semiconductor device in the system, and a method of manufacturing the semiconductor device in the system. The semiconductor device includes: a semiconductor region located in a semiconductor layer formed on an isolating layer; an ONO film on the semiconductor region; bit lines on either side of the semiconductor region, which are located in the semiconductor layer, and are in contact with the isolating layer; a device isolating region on two different sides of the semiconductor region from the sides on which the bit lines are located, the device isolating region being in contact with the isolating layer; and a first voltage applying unit that is coupled to the semiconductor region. In this semiconductor device, the semiconductor region is surrounded by the bit lines and the device isolating region, and is electrically isolated from other semiconductor regions.

Abstract: A technique is provided which allows easy achievement of a semiconductor device with desired breakdown voltage. In a high-potential island region defined by a p impurity region, an n+ impurity region is formed in an n? semiconductor layer, and first field plates and second field plates are formed in multiple layers above the n? semiconductor layer between the n+ impurity region and the p impurity region. The second field plates in the upper layer are located above spaces between the first field plates in the lower layer, over which an interconnect line passes. One of the second field plates which is closest to the p impurity region has a cut portion under the interconnect line, and an electrode is spaced between the first field plates located under the cut portion.