Abstract: One of the aspects of the present invention is to provide a semiconductor device, which includes a semiconductor layer of a first conductive type having first and second surfaces. The semiconductor layer includes a base region of a second conductive type formed in the first surface and an emitter region of the first conductive type formed in the base region. Also, the semiconductor device includes a buffer layer of the first conductive type formed on the second surface of the semiconductor layer, and a collector layer of the second conductive type formed on the buffer layer. The buffer layer has a maximal concentration of the first conductive type impurity therein of approximately 5×1015 cm?3 or less, and the collector layer has a maximal concentration of the second conductive type impurity therein of approximately 1×1017 cm?3 or more. Further, the ratio of the maximal concentration of the collector layer to the maximal concentration of the buffer layer being greater than 100.

Abstract: An over-voltage protection device includes a substrate including an upper surface and a lower surface; a first electrode provided on the upper surface of the substrate; a second electrode provided on the lower surface on the substrate; a first conductive layer overlying the lower surface of the substrate, the first conductive region being a conductive region of a first type; a plurality of first conductive regions provided proximate the upper surface of the substrate, the plurality of first conductive regions being conductive regions of the first type; and a plurality of second conductive region provided proximate the upper surface of the substrate, the plurality of second conductive region being conductive regions of a second type. The plurality of the first conductive regions are provided in an alternating manner with the plurality of second conductive regions. The first electrode is contacting the plurality of the first and second conductive regions.

Abstract: An integrated packaging assembly for an MMIC that uses the semiconductor wafers on which circuit elements are fabricated as the package. The packaging assembly includes a plurality of semiconductor layers that have been diced from the semiconductor wafers, where the semiconductor layers can be made of different semiconductor material. The semiconductor layers define cavities therebetween in which circuit components are fabricated. A sealing ring seals the semiconductor layers together so as to hermetically seal the circuit components within the cavities.

Abstract: A Schottky barrier diode includes a first semiconductor layer and a second semiconductor layer successively formed above a semiconductor substrate with a buffer layer formed between the first and second semiconductor layers and the semiconductor substrate. A Schottky electrode and an ohmic electrode spaced from each other are formed on the second semiconductor layer, and a back face electrode is formed on the back face of the semiconductor substrate. The Schottky electrode or the ohmic electrode is electrically connected to the back face electrode through a via penetrating through at least the buffer layer.

Abstract: The present invention addresses detection of charge-induced defects through test structures that can be easily incorporated on a wafer to detect charge-induced damage in the back-end-of-line processing of a semiconductor processing line. A test macro is designed to induce an arc from a charge accumulating antenna structure to another charge accumulating antenna structure across parallel plate electrodes. When an arc of a predetermined sufficient strength is present, the macro will experience a voltage breakdown that is measurable as a short. The parallel plate electrodes may both be at the floating potential of the microchip to monitor CMP-induced or lithographic-induced charge failure mechanisms, or have one electrode electrically connected to a ground potential structure to capture charge induced damage, hence having the capability to differentiate between the two.

Abstract: To reduce a reverse leakage current in a Schottky barrier diode with achieving a lower forward voltage Vf and a smaller capacitance than in the related art, a Schottky barrier diode includes a semiconductor layer of a first conductivity type, a first electrode which is a metal layer forming a Schottky contact with a main surface of the semiconductor layer, a second electrode forming an ohmic contact with an opposite main surface of the semiconductor layer, a buried layer of a second conductivity type formed within the semiconductor layer so as not to be in contact with the first electrode, where the second conductivity type has a different charge carrier from the first conductivity type, and a guard ring of the second conductivity type formed within the semiconductor layer so as to be in contact with the first electrode and also to surround the buried layer without contacting with the buried layer.

Abstract: An embodiment of the present invention is a technique to prevent reliability failures in semiconductor devices. A trench is patterned in a polyimide layer over a guard ring having a top metal layer. A passivation layer is etched at bottom of the trench. A capping layer is deposited on the trench over the etched passivation layer. The capping layer and the top metal layer form a mechanical strong interface to prevent a crack propagation.

Abstract: An electrostatic discharge (ESD) structure connected to a bonding pad in an integrated circuit comprising: a P-type substrate with one or more first P+ regions connected to a low voltage supply (GND), a first Nwell formed in the P-type substrate, one or more second P+ regions disposed inside the first Nwell and connected to the bonding pad, at least one first N+ region disposed outside the first Nwell but in the P-type substrate and connected to the GND, at least one second N+ region disposed outside the first Nwell but in the P-type substrate and connected to the bonding pad, wherein the second N+ region is farther away from the first Nwell than the first N+ region, and at least one conductive material disposed above the P-type substrate between the first and second N+ regions and coupled to the GND, wherein the first N+ region, the second N+ region and the conductive material form the source, drain and gate of an NMOS transistor, respectively, and the first P+ region is farther away from the first Nwell tha

Abstract: A method of deforming a pattern comprising the steps of: forming, over a substrate, a layered-structure with an upper surface including at least one selected region and at least a re-flow stopper groove, wherein the re-flow stopper groove extends outside the selected region and separate from the selected region; selectively forming at least one pattern on the selected region; and causing a re-flow of the pattern, wherein a part of an outwardly re-flowed pattern is flowed into the re-flow stopper groove, and then an outward re-flow of the pattern is restricted by the re-flow stopper groove extending outside of the pattern, thereby to form a deformed pattern with at least an outside edge part defined by an outside edge of the re-flow stopper groove.

Abstract: A method and apparatus are provided for protecting a semiconductor device from damage. The method includes the steps of providing a active semiconductor device on a surface of the semiconductor substrate where the active device is surrounded by inactive semiconductor areas and providing a soft metallic guard ring only in the inactive semiconductor areas around the periphery of the active device wherein the metallic guard ring is connected to ground potential and not to the active device.

Abstract: A method of making a semiconductor structure for use in a static induction transistor. Three layers of a SiC material are on a substrate with the top layer covered with a thick oxide. A mask having a plurality of strips is deposited on the top of the oxide to protect the area underneath it, and an etch removes the oxide, the third layer and a small amount of the second layer, leaving a plurality of pillars. An oxidation step grows an oxide skirt around the base of each pillar and consumes the edge portions of the third layer under the oxide to form a source. An ion implantation forms gate regions between the skirts. At the same time, a plurality of guard rings is formed. Removal of all oxide results in a semiconductor structure to which source, gate and drain connections may be made to form a static induction transistor. A greater separation between a source and gate is obtained by placing a spacer layer on the sidewalls of the pillars, either before or after formation of the skirt.

Abstract: A semiconductor device is disclosed. The device includes a substrate and a first wiring layer overlying the substrate. The first wiring layer comprises a first wiring area surrounded by a first seal ring. The first seal ring comprises a first monitor circuit isolated by a first dielectric layer embedded in the first seal ring. The first monitor circuit is responsive to a predetermined amount of deformation occurs in the third dielectric layer.

Abstract: A termination region of a semiconductor die is provided, which includes one or more field rings arranged in the termination region, one or more metal field plates, and an insulation layer disposed to prevent direct electrical contact between the field rings and the field plate such that the at least one field ring is capacitively coupled with the at least one field plate. Such a termination region may also include a polysilicon plate capacitively coupled with a diffusion region laterally spaced from the field rings, the polysilicon plate being located at an outer surface or directly under a passivation layer at an outer surface of the die. The termination region may also include floating field rings. The insulation layer may be a field oxide layer.

Abstract: A fuse area of a semiconductor device capable of preventing moisture-absorption and a method for manufacturing the fuse area are provided. When forming a guard ring for preventing permeation of moisture through the sidewall of an exposed fuse opening portion, an etch stop layer is formed over a fuse line. A guard ring opening portion is formed using the etch stop layer. The guard ring opening portion is filled with a material for forming the uppermost wiring of multi-level interconnect wirings or the material of a passivation layer, thereby forming the guard ring concurrently with the uppermost interconnect wiring or the passivation layer. Accordingly, permeation of moisture through an interlayer insulating layer or the interface between interlayer insulating layers around the fuse opening portion can be efficiently prevented by a simple process.

Abstract: Disclosed are a variety of junction termination structures for high voltage semiconductor power devices. The structures are specifically aimed at providing a high breakdown voltage while being constructed with a minimal number of process steps. The combination of an RIE etch and/or implantation and anneal process with a finely patterned mesh provides the desired radial gradient for maximum breakdown voltage. The structures provide control of both the conductivity and charge density within the region. These structures can beneficially be applied to all high voltage semiconductor device structures, but are of particular interest for wide bandgap devices as they tend to have very high breakdown fields and scaled dimensions of the depletion layer width.

Abstract: An integrated circuit structure for isolating substrate noise and a method of forming the same are provided. In the preferred embodiment of the present invention, a semi-insulating region is formed using proton bombardment in a substrate between a first circuit region and a second circuit region. Two guard rings are formed along the semi-insulating region, each on a side. A backside semi-insulating region is formed through proton bombardment from the back surface of the substrate into the substrate. The backside semi-insulating region is preferably connected with the semi-insulating region. A grounded guard layer is preferably formed on the backside semi-insulating region.

Abstract: A trench type Schottky device has a guard ring diffusion of constant depth between the outermost of an active trench and an outer surrounding termination trench. The junction curvature of the guard ring diffusion is suppressed or cut out by the trenches.

Abstract: A seal ring structure is formed through a multilayer structure of a plurality of dielectric films in a peripheral part of a chip region to surround the chip region. A dual damascene interconnect in which an interconnect and a plug connected to the interconnect are integrated is formed in at least one of the dielectric films in the chip region. Part of the seal ring structure formed in the dielectric film in which the dual damascene interconnect is formed is continuous. A protection film formed on the multilayer structure has an opening on the seal ring. A cap layer connected to the seal ring is formed in the opening.

Abstract: A gallium nitride based semiconductor Schottky diode fabricated from a n+ doped GaN layer having a thickness between one and six microns disposed on a sapphire substrate; an n? doped GaN layer having a thickness greater than one micron disposed on said n+ GaN layer patterned into a plurality of elongated fingers and a metal layer disposed on the n? doped GaN layer and forming a Schottky junction therewith. The layer thicknesses and the length and width of the elongated fingers are optimized to achieve a device with breakdown voltage of greater than 500 volts, current capacity in excess of one ampere, and a forward voltage of less than three volts.

Abstract: In one embodiment, a semiconductor structure comprises a multi-portioned guard ring that includes a first portion and a second portion formed in a region of semiconductor material. A conductive contact layer forms a first Schottky barrier with the region of semiconductor material. The conductive contact layer overlaps the second portion and forms a second Schottky barrier that has an opposite polarity to the first Schottky barrier. The conductive contact layer does not overlap the first portion, which forms a pn junction with the region of semiconductor material.

Abstract: In one embodiment, a Schottky diode structure comprises a Schottky barrier layer in contact with a semiconductor material through a Schottky contact opening. A conductive ring is formed adjacent the Schottky contact opening and is separated from the semiconductor material by a thin insulating layer. Another insulating layer is formed overlying the structure, and a contact opening is formed therein. The contact opening is wider than the Schottky contact opening and exposes portions of the conductive ring. A Schottky barrier metal is formed in contact with the semiconductor material through the Schottky contact opening, and is formed in further+contact with the conductive ring.

Abstract: A method of avoiding substrate noise in an integrated circuit includes steps of receiving as input an integrated circuit design that includes at least a portion of a block for placement and routing on a substrate and an outer boundary of the block. An end cell is selected from a set of end cells for terminating the block in an outer area that extends from the outer boundary to an end cell boundary outside the block. The selected end cell is placed in the outer area to isolate the block electrically from the substrate.

Abstract: Methods and structures and methods of designing structures for charge dissipation in an integrated circuit on an SOI substrate. A first structure includes a charge dissipation ring around a periphery of the integrated circuit chip and one or more charge dissipation pedestals physically and electrically connected to the charge dissipation pedestals. The silicon layer and bulk silicon layer of the SOI substrate are connected by the guard ring and the charge dissipation pedestals. The ground distribution grid of the integrated circuit chip is connected to an uppermost wire segment of one or more charge dissipation pedestals. A second structure, replaces the charge dissipation guard ring with additional charge dissipation pedestal elements.

Abstract: Disclosed herein are novel damage detection circuitries implemented on the periphery of a semiconductor device. The circuitries disclosed herein enable the easy identification of cracks and deformation, and other types of damage that commonly occur during test and assembly processes of semiconductor devices.

Abstract: A semiconductor device including: a semiconductor layer; a gate insulating layer; a gate electrode; a channel region; a source region and a drain region; a guard ring region; an offset insulating layer; a first interlayer dielectric; a first shield layer formed above the first interlayer dielectric and the guard ring region and electrically connected to the guard ring region; a second interlayer dielectric; and a second shield layer formed above the second interlayer dielectric, wherein the first shield layer is provided outside of both ends of the gate electrode in a channel width direction when viewed from the top side; and wherein the second shield layer is provided in at least part of a first region and/or at least part of a second region, the first region being a region between one edge of the gate electrode and an edge of the first shield layer opposite to the edge of the gate electrode in the channel width direction when viewed from the top side, and the second region being a region between the other e

Abstract: A semiconductor device has a semiconductor device chip with upper and lower terminal electrodes, and upper and lower frames bonded to the upper and lower terminal electrodes, respectively, with solder material, wherein the semiconductor device chip includes: a semiconductor layer of a first conductivity type; a diffusion layer of a second conductivity type, which is selectively formed in the semiconductor layer; a plurality of guard-ring layers of the second conductivity type, which are formed outside of the diffusion layer in the semiconductor layer; an insulating film formed on the semiconductor layer; and a field plate formed of a poly-crystalline silicon film embedded in the insulating film.

Abstract: A chip package including a carrier, a chip, a stiffener and a molding compound is provided. A producing method of the chip package includes the steps of disposing a bottom surface of the chip on the carrier; covering an edge of a top surface of the chip with the stiffener for protecting the edge; then wire bonding the top surface of the chip with the carrier; and forming the molding compound for encapsulating the chip, the stiffener and parts of the carrier.

Abstract: An electronic device includes a substrate, an insulating layer arranged on the substrate, the insulating layer having an opening in an area of the surface of the substrate, an active layer arranged within the opening on the surface of the substrate, the active layer including a guard ring in those areas of the surface and of the active layer which are adjacent to the insulating layer, and a contacting layer arranged on an area of the active layer, the contact layer being adjacent to an area of the guard ring. The device may be produced by a process of three-fold self-alignment, to be precise utilizing a spacer process by means of which a diffusion source having a lateral extension far below the lithography limit is made possible.

Abstract: A semiconductor device of unipolar type has Schottky-contacts (6) laterally separated by regions in the form of additional layers (7, 7?) of semiconductor material on top of a drift layer (3). Said additional layers being doped according to a conductivity type being opposite to the one of the drift layer. At least one (7?) of the additional layers has a substantially larger lateral extension and thereby larger area of the interface to the drift layer than adjacent such layers (7) for facilitating the building-up of a sufficient voltage between that layer and the drift layer for injecting minority charge carriers into the drift layer upon surge for surge protection.

Abstract: A diode is provided which includes a first-conductivity-type cathode layer, a first-conductivity-type drift layer placed on the cathode region and having a lower concentration than the cathode layer, a generally ring-like second-conductivity-type ring region formed in the drift layer, second-conductivity-type anode region formed in the drift layer located inside the ring region, a cathode electrode formed in contact with the cathode layer, and an anode electrode formed in contact with the anode region, wherein the lowest resistivity of the second-conductivity-type anode region is at least 1/100 of the resistivity of the drift layer, and the thickness of the anode region is smaller than the diffusion depth of the ring region.

Abstract: A retaining ring for use with electrochemical mechanical processing is described. The retaining ring has a generally annular body formed with a conductive portion and a non-conductive portion. The non-conductive portion contacts the substrate during polishing. The conductive portion is electrically biased during polishing to reduce the edge effect that tends to occur with conventional electrochemical mechanical processing systems.

Abstract: A trench transistor has a cell array, in which at least one cell array trench (2) is provided, and an edge structure framing the cell array. An edge trench (15) spaced apart from the cell array trenches (2) is provided in the edge structure.

Abstract: A method of forming an improved seal ring structure is described. A continuous metal seal ring is formed along a perimeter of a die wherein the metal seal ring is parallel to the edges of the die and sloped at the corner of the die so as not to have a sharp corner and wherein the metal seal ring has a first width at the corners and a second width along the edges wherein the first width is wider than the second width.

Abstract: There is here disclosed a film forming ring including a ring main body being made of an insulating material and formed in an annular shape along an edge of a substrate on which a film forming process by using a material gas in a plasma state is applied, and an inner rim of the ring main body being formed higher than its outside portion.

Abstract: A diode is provided which includes a first-conductivity-type cathode layer, a first-conductivity-type drift layer placed on the cathode region and having a lower concentration than the cathode layer, a generally ring-like second-conductivity-type ring region formed in the drift layer, second-conductivity-type anode region formed in the drift layer located inside the ring region, a cathode electrode formed in contact with the cathode layer, and an anode electrode formed in contact with the anode region, wherein the lowest resistivity of the second-conductivity-type anode region is at least 1/100 of the resistivity of the drift layer, and the thickness of the anode region is smaller than the diffusion depth of the ring region.

Abstract: In mixed-component, mixed-signal, semiconductor devices, selective seal ring isolation from the substrate and its electrical potential is provided in order to segregate noise sensitive circuitry from electrical noise generated by electrically noisy circuitry. Appropriate predetermined sections of such a mixed use chip are isolated from the substrate through a non-ohmic contact with the substrate without compromising reliability of the chip's isolation from scribe region contamination.

Abstract: An LDMOS transistor has a Schottky diode inserted at the center of a doped region of the LDMOS transistor. A Typical LDMOS transistor has a drift region in the center. In this case a Schottky diode is inserted at the center of this drift region which has the effect of providing a Schottky diode connected from source to drain in the forward direction so that the drain voltage is clamped to a voltage that is lower than the PN junction threshold, thereby avoiding forward biasing the PN junction. An alternative is to insert the Schottky diode at the well in which the source is formed, which is on the periphery of the LDMOS transistor. In such case the Schottky diode is formed differently but still is connected from source to drain in the forward direction to achieve the desired voltage clamping at the drain.

Abstract: A semiconductor device having improved breakdown voltage is provided. A diode device of the present invention includes relay diffusion layers provided between guard ring portions. Therefore, a depletion layer expanded outward from the guard ring portions except the outermost one reaches these relay diffusion layers, and then the outer guard ring portions. The width of the distance between the guard ring portions is shorter where the relay diffusion layers are provided. For the width of the relay diffusion layers, the depletion layer reaches the outer guard ring portions with a lower voltage than the conventional structure.

Abstract: A chip-scale schottky package which has at least one cathode electrode and at least one anode electrode disposed on only one major surface of a die, and solder bumps connected to the electrode for surface mounting of the package on a circuit board.

Abstract: A diode is provided which includes a first-conductivity-type cathode layer, a first-conductivity-type drift layer placed on the cathode region and having a lower concentration than the cathode layer, a generally ring-like second-conductivity-type ring region formed in the drift layer, second-conductivity-type anode region formed in the drift layer located inside the ring region, a cathode electrode formed in contact with the cathode layer, and an anode electrode formed in contact with the anode region, wherein the lowest resistivity of the second-conductivity-type anode region is at least 1/100 of the resistivity of the drift layer, and the thickness of the anode region is smaller than the diffusion depth of the ring region.

Abstract: Schottky barrier diodes use a dielectric separation region to bound an active region. The dielectric separation region permits the elimination of a guard ring in at least one dimension. Further, using a dielectric separation region in an active portion of the integrated circuit device may reduce or eliminate parasitic capacitance by eliminating this guard ring.

Abstract: A fast recovery diode has a single large area P/N junction surrounded by a termination region. The anode contact in contact with the central active area extends over the inner periphery of an oxide termination ring and an EQR metal ring extends over the outer periphery of the oxide termination ring. Platinum atoms are diffused into the back surface of the device. A three mask process is described. An amorphous silicon layer is added in a four mask process, and a plurality of spaced guard rings are added in a five mask process.

Abstract: A Merged P-i-N Schottky device in which the oppositely doped diffusions extend to a depth and have been spaced apart such that the device is capable of absorbing a reverse avalanche energy comparable to a Fast Recovery Epitaxial Diode having a comparatively deeper oppositely doped diffusion region.

Abstract: A power Schottky rectifier device having pluralities of trenches are disclosed. The Schottky barrier rectifier device includes field oxide region having p-doped region formed thereunder to avoid premature of breakdown voltage and having a plurality of trenches formed in between field oxide regions to increase the anode area thereto increase forward current capacity or to shrinkage the planar area for driving the same current capacity. Furthermore, the trenches have rounded corners to alleviate current leakage and LOCOS region in the active region to relief stress during the bonding process. The processes for power Schottky barrier rectifier device including termination region formation need only three masks and thus can gain the benefits of cost down.

Abstract: To reduce a reverse leakage current in a Schottky barrier diode with achieving a lower forward voltage Vf and a smaller capacitance than in the related art, a Schottky barrier diode includes a semiconductor layer of a first conductivity type, a first electrode which is a metal layer forming a Schottky contact with a main surface of the semiconductor layer, a second electrode forming an ohmic contact with an opposite main surface of the semiconductor layer, a buried layer of a second conductivity type formed within the semiconductor layer so as not to be in contact with the first electrode, where the second conductivity type has a different charge carrier from the first conductivity type, and a guard ring of the second conductivity type formed within the semiconductor layer so as to be in contact with the first electrode and also to surround the buried layer without contacting with the buried layer.

Abstract: A substrate contact and semiconductor chip, and methods of forming the same. The substrate contact is employable with a semiconductor chip formed from a semiconductor substrate and includes a seal ring region about a periphery of an integrated circuit region. In one embodiment, the substrate contact includes a contact trench extending through a shallow trench isolation region and an insulator overlying the semiconductor substrate and outside the integrated circuit region. The contact trench is substantially filled with a conductive material thereby allowing the semiconductor substrate to be electrically connected with a metal interconnect within the seal ring region.

Abstract: An integrated circuit includes a high voltage Schottky barrier diode and a low voltage device. The Schottky barrier diode includes a lightly doped p-well as guard ring while the low voltage devices are built using standard, more heavily doped p-wells. By using a process including a lightly doped p-well and a standard p-well, high voltage and low voltage devices can be integrated onto the same integrated circuit. In one embodiment, the lightly doped p-well and the standard p-well are formed by performing ion implantation using a first dose to form the lightly doped p-well, masking the lightly doped p-well, and performing ion implantation using a second dose to form the standard p-well. The second dose is the difference of the dopant concentrations of the lightly doped p-well and the standard p-well. In other embodiments, other high voltage devices can also be built by incorporating the lightly doped p-well structure.

Abstract: A phase change memory may be made using an isolation diode in the form of a Shottky diode between a memory cell and a word line. To reduce the leakage currents associated with the Shottky diode, a guard ring may be utilized.

Abstract: A diode is provided which includes a first-conductivity-type cathode layer, a first-conductivity-type drift layer placed on the cathode region and having a lower concentration than the cathode layer, a generally ring-like second-conductivity-type ring region formed in the drift layer, second-conductivity-type anode region formed in the drift layer located inside the ring region, a cathode electrode formed in contact with the cathode layer, and an anode electrode formed in contact with the anode region, wherein the lowest resistivity of the second-conductivity-type anode region is at least 1/100 of the resistivity of the drift layer, and the thickness of the anode region is smaller than the diffusion depth of the ring region.

Abstract: A method for producing a semiconductor component with adjacent Schottky (5) and pn (9) junctions positions in a drift area (2, 10) of a semiconductor material. According to the method, a silicon carbide substrate doped with a first doping material of at least 1018 cm?3 is provided, and a silicon carbide layer with a second doping material of the same charge carrier type in the range of 1014 and 1017 cm?3 is homo-epitaxially deposited on the substrate. A third doping material with a complimentary charge carrier is inserted, and structured with the aid of a diffusion and/or ion implantation, on the silicon carbide layer surface that is arranged far from the substrate to form pn junctions. Subsequently the component is subjected to a first temperature treatment between 1400° C. and 1700° C. Following this temperature treatment, a first metal coating is deposited on the implanted surface in order to form a Schottky contact and then a second metal coating is deposited in order to form an ohmic contact.