Abstract: A semiconductor device including a substrate; gate structures spaced apart from each other on the substrate, each gate structure including a gate electrode and a gate capping pattern; source/drain patterns on opposite sides of the gate structures; first isolation patterns that respectively penetrate adjacent gate structures; and a second isolation pattern that extends between adjacent source/drain patterns, and penetrates at least one gate structure, wherein each first isolation pattern separates the gate structures such that the gate structures are spaced apart from each other, the first isolation patterns are aligned with each other, and top surfaces of the first and second isolation patterns are each located at a level the same as or higher than a level of a top surface of the gate capping pattern.

Abstract: A bidirectional thyristor device includes a semiconductor wafer with a number of layers forming pn junctions. A first main electrode and a first gate electrode are arranged on a first main side of the wafer. A second main electrode and a second gate electrode are arranged on a second main side of the wafer. First emitter shorts penetrate through a first semiconductor layer and second emitter shorts penetrate through a fifth semiconductor layer. In an orthogonal projection onto a plane parallel to the first main side, a first area occupied by the first semiconductor layer and the first emitter shorts overlaps in an overlapping area with a second area occupied by the fifth semiconductor layer and the second emitter shorts. The overlapping area, in which the first area overlaps with the second area, encompasses at least 50% of a total wafer area occupied by the semiconductor wafer.

Abstract: To prevent contact plugs formed to sandwich an abutting portion between gate electrodes, from being short-circuited via a void formed inside an insulating film of the abutting portion. Over sidewalls SW facing each other in the abutting portion between gate electrodes G2 and G5, a liner insulating film 6 and an interlayer insulating film 7 are formed. Between the sidewalls SW, the liner insulating film 6 formed on each of the side walls of the sidewalls SW are brought in contact with each other to close a space between the sidewalls SW to prevent a void from being generated inside the interlayer insulating film 7 and the liner insulating film 6.

Abstract: The present invention is directed to novel front side illuminated, back side contact photodiodes and arrays thereof. In one embodiment, the photodiode has a substrate with at least a first and a second side and a plurality of electrical contacts physically confined to the second side. The electrical contacts are in electrical communication with the first side through a doped region of a first type and a doped region of a second type, each of the regions substantially extending from the first side through to the second side. In another embodiment, the photodiode comprises a wafer with at least a first and a second side; and a plurality of electrical contacts physically confined to the second side, where the electrical contacts are in electrical communication with the first side through a diffusion of a p+ region through the wafer and a diffusion of an n+ region through the wafer.

Abstract: A main semiconductor region grown on a substrate has formed on its surface a pair of main electrodes spaced from each other, a gate electrode between the main electrodes, and a pair of diode-forming electrodes spaced farther away from the gate electrode than are the main electrodes. Making ohmic contact with the main semiconductor region, the pair of main electrodes serve both as drain or source of a HEMT switch and as cathodes of a pair of Schottky diodes integrated with the HEMT switch. Both gate electrode and diode-forming electrodes are in Schottky contact with the main semiconductor region.

Abstract: Disclosed are embodiments of a wafer that incorporates fill structures with varying configurations to provide uniform reflectance. Uniform reflectance is achieved by distributing across the wafer fill structures having different semiconductor materials such that approximately the same ratio and density between the different semiconductor materials is achieved within each region and, optimally, each sub-region. Alternatively, it is achieved by distributing across the wafer fill structures, including one or more hybrid fill structure containing varying proportions of different semiconductor materials, such that approximately the same ratio between the different semiconductor materials is achieved within each region and, optimally, each sub-region.

Abstract: A semiconductor device includes a first conductive type SiC semiconductor substrate; a second conductive type well formed on the SiC semiconductor substrate; a first impurity diffusion layer formed by introducing a first conductive type impurity so as to be partly overlapped with the well in a region surrounding the well; a second impurity diffusion layer formed by introducing the first conductive type impurity in a region spaced apart for a predetermined distance from the impurity diffusion layer in the well; and a gate electrode opposed to a channel region between the first and the second impurity diffusion layers with gate insulating film sandwiched therebetween.

Abstract: A transistor includes a control electrode, a first current electrode and a second current electrode. The control electrode includes a body portion, and first and second hand portions protruded from first and second ends of the body portion, respectively. The first current electrode is electrically insulated from the control electrode and disposed over a region between the first and second hand portions of the control electrode. A portion of the first current electrode is overlapped with a portion of the control electrode. The second current electrode is electrically insulated from the control electrode and partially overlapped with the body portion, the first hand portion and the second hand portion of the control electrode. Therefore, parasitic capacitance is reduced.

Abstract: A pinned photodiode sensor with gate-controlled SCR switch includes a pinned photodiode and a gate-controlled SCR switch. The SCR switch includes a P-type substrate, an N? doped region, and an N+ doped region formed on the substrate; a P+ doped region formed on the N? doped region; an oxide layer formed on the P substrate, the N? doped region, the N+ doped region, and the P+ doped region; and a gate formed above the P substrate and the N? doped region. The gate includes a P+ doped region and an N+ doped region. During an exposure procedure, a depletion region will not reach the interface between the oxide layer and the substrate, thereby preventing dark current leakage.

Abstract: High voltage silicon carbide (SiC) devices, for example, thyristors, are provided. A first SiC layer having a first conductivity type is provided on a first surface of a voltage blocking SiC substrate having a second conductivity type. A first region of SiC is provided on the first SiC layer and has the second conductivity type. A second region of SiC is provided in the first SiC layer, has the first conductivity type and is adjacent to the first region of SiC. A second SiC layer having the first conductivity type is provided on a second surface of the voltage blocking SiC substrate. A third region of SiC is provided on the second SiC layer and has the second conductivity type. A fourth region of SiC is provided in the second SiC layer, has the first conductivity type and is adjacent to the third region of SiC. First and second contacts are provided on the first and third regions of SiC, respectively. Related methods of fabricating high voltage SiC devices are also provided.

Abstract: Embodiments of the present invention disclose a memory device having an array of flash memory cells with source contacts that facilitate straight word lines, and a method for producing the same. The array is comprised of a plurality of non-intersecting shallow trench isolation (STI) regions that isolate a plurality of memory cell columns. A source column is implanted with n-type dopants after the formation of a tunnel oxide layer and a first polysilicon layer. The implanted source column is coupled to a plurality of common source lines that are coupled to a plurality of source regions associated with memory cells in the array. A source contact is coupled to the implanted source column for providing electrical coupling with the plurality of source regions. The source contact is collinear with a row of drain contacts that are coupled to drain regions associated with a row of memory cells. The arrangement of source contacts collinear with the row of drain contacts allows for straight word line formation.

Abstract: An interconnect for testing a semiconductor component includes a substrate, and interconnect contacts on the substrate configured to electrically engage component contacts on a semiconductor component. Each interconnect contact includes a compliant conductive layer formed as a conductive spring element. In addition, the complaint conductive layer includes a tip for engaging the component contact and a spring segment portion for resiliently supporting the tip. A method for fabricating the interconnect includes the steps of shaping the substrate, forming a conductive layer on a shaped portion of the substrate and removing at least some of the shaped portion. The shaped portion can comprise a raised step or dome, or a shaped recess in the substrate. The conductive layer can comprise a metal, a conductive polymer or a polymer tape can include a penetrating structure or penetrating particles.

Abstract: A method and apparatus for coupling to a common line in an array. Gate structures of an integrated circuit are formed. Source and drain regions adjacent to the gate structures are implanted. A source contact from a metal Vss line to a source region is formed. Dopants of the source and drain regions diffuse laterally to overlap. The overlapping diffusion regions conduct and couple the drain region to a source region. Beneficially, the drain region is coupled to the metal Vss line. As a beneficial result, source contacts may be formed along a line of drain contacts in associated rows of drain contacts, and coupled to a common source line via the novel overlapping diffusion regions. A plurality of word lines may be formed without any bending in the word lines to accommodate source contacts that are larger than the source line.

Abstract: An ESD-protection structure is located substantially under an integrated circuit bond pad. This ESD-protection structure is formed as a low capacitance structure by inserting a forward diode between the bond pad and the ESD clamp circuit. Placing the ESD-protection structure under the bond pad eliminates parasitic substrate capacitance and utilizes a parasitic PNP transistor formed from the inserted forward biased diode. The ESD-protection structure includes adjacent alternating P+ and N+ diffusions located substantially under a bond pad to be ESD protected. The P+ diffusions are connected to the bond pad metal with metal vias through an insulating layer. The N+ diffusions are adjacent to the P+ diffusions. An N+ diffusion surrounds the N+ and P+ diffusions, and ties together the N+ diffusions so as to form a continuous N+ diffusion completely around each of the P+ diffusions. An N? well is located substantially under the N+ and P+ diffusions.

Abstract: A vertical voltage-controlled bidirectional monolithic switch formed between the upper and lower surfaces of a semiconductor substrate surrounded with a peripheral wall, including: a first multiple-cell vertical IGBT transistor extending between a cathode formed on the upper surface side and an anode formed on the lower surface side; and a second multiple-cell vertical IGBT transistor extending between a cathode formed on the lower surface side and an anode formed on the upper surface side, in which the cells of each transistor are arranged so that portions of the cells of a transistor are active upon operation of the other transistor.

Abstract: In an aspect, an apparatus is provided that sets and reprograms the state of programmable devices. In an aspect, a method is provided such that an opening is formed through a dielectric exposing a contact, the contact formed on a substrate. An electrode is conformally deposited on a wall of the dielectric, utilizing atomic layer deposition (ALD). A programmable material is formed on the electrode and a conductor is formed to the programmable material. In an aspect, a barrier is conformally deposited utilizing ALD, between the electrode and the programmable material.

Abstract: A high power rectifier device has an − drift layer on an N+ layer. A number of trench structures are recessed into the drift layer opposite the N+ layer; respective mesa regions separate each pair of trenches. Each trench structure includes oxide side-walls and an oxide bottom, and is filled with a conductive material. A metal layer contacts the trench structures and mesa regions, forming Schottky contacts at the metal-mesa interface. Shallow P regions extend from the bottom of each trench into the drift layer. Forward conduction occurs when the Schottky contact's barrier height is overcome. When reversed-biased, depletion regions form around the shallow P regions and the oxide side-walls which provide potential barriers across the mesa regions that shield the Schottky contacts from high electric fields, providing a high reverse blocking voltage and reducing reverse leakage current.

Abstract: A vertical semiconductor component has an integrated switching device, which delivers an electric value correlating with the rear potential. The semiconductor component includes a doping region with a hole, which is free of the doping atoms of the doping region. The hole, when properly sized and contacted, can supply an electric current correlating with the rear potential.

Abstract: A specification is given of a bidirectionally controllable thyristor which is distinguished by improved decoupling between the two thyristor structures. In particular, the intention is that the switched-off structure cannot be triggered in an uncontrolled manner by undesirable migration of charge carriers. This is achieved by virtue of the fact that the degree of shorting of the cathode region increases toward the isolation region. In particular, this can be achieved by virtue of the fact that the density per unit area of the short-circuit regions tends to a maximum value toward the isolation region. The use of a linear, continuous short-circuit region running along the isolation region is particularly favorable. (FIG. 1).

Abstract: A circuit for protecting a bonding pad of a semiconductor device from ESD voltages is located under the pad to permit the space otherwise used for a protection circuit to be used for normal operating components. The protection circuit has a compact layout that provides maximum ability to handle an ESD current within this limited space. The semiconductor structure for the circuit has separate parts for two SCR circuits, one for each polarity of ESD current. Each SCR circuit comprises two symmetrical SCR structures.

Abstract: A reverse conducting gate-turnoff thyristor includes a switching device section, a diode section, and an isolating section located between the switching device section and the diode section. The isolating section includes an impurity layer formed by controlling impurity diffusion and having an impurity concentration lower than those of the switching device section and the diode section.

Abstract: A bidirectional thyristor structure with a single MOS gate controlled turn off capability. In a vertical conduction embodiment, the device has a six layer structure including a backside diffusion. One vertical conduction structure includes a single body region at the first surface of the device for conduction in both the forward and reverse directions. Another vertical conduction structure includes a two body regions at the first surface, one for controlling forward conduction and the other for controlling reverse conduction. The vertical conduction embodiments are preferably implemented in a cellular geometry, with a large number of symmetrical cells connected in parallel. The bidirectional thyristor of the present invention can also be provided in a lateral conduction structure for power IC applications.

Abstract: A bidirectional thyristor structure with a single MOS gate controlled turn-on and turn-off capability. In a vertical conduction embodiment, the device has a six layer structure including a backside diffusion. One vertical conduction structure includes a single body region at the first surface of the device for conduction in both the forward and reverse directions. Another vertical conduction structure includes a two body regions at the first surface, one for controlling forward conduction and the other for controlling reverse conduction. The vertical conduction embodiments are preferably implemented in a cellular geometry, with a large number of symmetrical cells connected in parallel.

Abstract: A bidirectional thyristor structure with a single MOS gate controlled turn off capability. In a vertical conduction embodiment, the device has a six layer structure including a backside diffusion. One vertical conduction structure includes a single body region at the first surface of the device for conduction in both the forward and reverse directions. Another vertical conduction structure includes a two body regions at the first surface, one for controlling forward conduction and the other for controlling reverse conduction. The vertical conduction embodiments are preferably implemented in a cellular geometry, with a large number of symmetrical cells connected in parallel. The bidirectional thyristor of the present invention can also be provided in a lateral conduction structure for power IC applications.

Abstract: A thyristor with insulated gates includes turn-off and turn-on MOSFETs. The turn-on MOSFET has a turn-on gate employing a p-type base as a channel and extending over an n-type base and an n-type emitter. The turn-off MOSFET has n-type drain and source layers formed in a p-type base layer, and a turn-off gate extending over the drain and source layers. The n-type drain layer is short-circuited with the p-type base layer via a drain electrode. The drain electrode is formed near an n-type emitter layer. When the thyristor is to be turned off, the first voltage is applied to the turn-on gate, and the second voltage is applied to the turn-off gate while the first voltage is applied to the turn-on gate. After the application of the second voltage continues for a predetermined period of time, the application of the first voltage to the turn-on gate is stopped. With this operation, the thyristor can be turned off even with a large current.

Abstract: A voltage controlled thyristor includes an intrinsic layer of material between an anode and a cathode and a gate region between the intrinsic layer and the cathode comprising a lightly doped P type layer with more heavily doped P type regions extending through the lightly doped layer into the intrinsic layer. The more heavily doped P type regions are interspersed among shallower N doped regions of the cathode. In a preferred embodiment, interdigitated ohmic contacts are formed on one surface to the N doped cathode regions and the P doped regions of the control gate. In a preferred embodiment, the anode and cathode emitters have a porous construction in which a lightly doped layer or region has a more heavily doped region or regions therein.

Abstract: A GTO thyristor includes a p-type emitter layer, an n-type base layer, a p-type base layer and an n-type emitter layer. An additional n-type layer is formed on the p-type base layer next to the n-type emitter layer An additional p.sup.+ -type layer is formed on the additional n-type layer and stretches to the n-type emitter layer. An anode electrode and a cathode electrode are disposed respectively on the n-type emitter layer and the p-type base layer. The n-type emitter layer and the additional p.sup.+ -type layer are connected with each other by a floating electrode. A first gate electrode is disposed on the additional p.sup.+ -type layer, additional n-type layer and p-type base layer with an insulating film interposed therebetween so as to form a first FET. A second gate electrode is disposed on the n-type base layer, p-type base layer and n-type emitter layer with an insulating film interposed therebetween so as to form a second FET.

Abstract: A switching device includes a thyristor and a MOSFET, and a voltage clamp circuit. The voltage clamp circuit includes an N.sup.+ type contact region formed in a surface layer of a N type substrate and electrically connected to a gate electrode of a MOSFET, and a P type guard ring surrounding the contact region.

Abstract: According to this invention, there is disclosed an insulated gate GTO thyristor comprising a pnpn structure including a p-type emitter layer, an n-type base layer, a p-type base layer, and an n-type emitter layer. The thyristor has a first gate electrode contacting the p-type base layer and a second gate electrode formed on a channel region of the p-type base layer through a gate insulating film. An n+-type layer of the n-type emitter layer immediately below a cathode electrode and an n--type layer of the n-type emitter layer contacting the channel region are formed in different manufacturing steps, and an emitter breakdown voltage and the threshold voltage of the second gate electrode are optimally set.