Abstract: A semiconductor device including polysilicon (poly-Si) and method of manufacturing the same are provided. The semiconductor device includes a TaNx material layer and a poly-Si layer formed on the TaNx material layer. The semiconductor device including poly-Si may be manufactured by forming a TaNx material layer and forming a poly-Si layer by depositing silicon formed on the TaNx material layer and annealing silicon.

Abstract: New Group III based diodes are disclosed having a low on state voltage (Vf) and structures to keep reverse current (Irev) relatively low. One embodiment of the invention is Schottky barrier diode made from the GaN material system in which the Fermi level (or surface potential) of is not pinned. The barrier potential at the metal-to-semiconductor junction varies depending on the type of metal used and using particular metals lowers the diode's Schottky barrier potential and results in a Vf in the range of 0.1-0.3V. In another embodiment a trench structure is formed on the Schottky diodes semiconductor material to reduce reverse leakage current. and comprises a number of parallel, equally spaced trenches with mesa regions between adjacent trenches. A third embodiment of the invention provides a GaN tunnel diode with a low Vf resulting from the tunneling of electrons through the barrier potential, instead of over it. This embodiment can also have a trench structure to reduce reverse leakage current.

Abstract: A substrate diode of an SOI device may be formed on the basis of contact regions in an early manufacturing stage, i.e., prior to patterning gate electrode structures of transistors, thereby imparting superior stability to the sensitive diode regions, such as the PN junction. In some illustrative embodiments, only one additional deposition step may be required compared to conventional strategies, thereby providing a very efficient overall process flow.

Abstract: A semiconductor device includes a diode, a passivation layer and a conductive layer. The diode includes an epitaxial layer on a semiconductor substrate, and first and second diode contacts on different planes. The passivation layer has a planar top surface, and includes multiple consecutive layers of a benzocyclobutene (BCB) material formed on the diode, an aggregate thickness of the passivation layer exceeding a thickness of the epitaxial layer. The conductive layer is formed on the top surface of passivation layer, the conductive layer connecting with the first and the second diodes contact through first and second openings in the passivation layer, respectively. The passivation layer enhances a capacitive isolation between the conductive layer and the diode.

Abstract: A power semiconductor device, such as a power diode, and a method for producing such a device, are disclosed. The device includes a first layer of a first conductivity type, a second layer of a second conductivity type arranged in a central region on a first main side of the first layer, a third electrically conductive layer arranged on the second layer, and a fourth electrically conductive layer arranged on the first layer at a second main side opposite to the first main side. A junction termination region surrounds the second layer with self-contained sub-regions of the second conductivity type. A spacer region is arranged between the second layer and the junction termination region and includes a self-contained spacer sub-region of the second conductivity type which is electrically disconnected from the second layer.

Abstract: A carbon/tunneling-barrier/carbon diode and method for forming the same are disclosed. The carbon/tunneling-barrier/carbon may be used as a steering element in a memory array. Each memory cell in the memory array may include a reversible resistivity-switching element and a carbon/tunneling-barrier/carbon diode as the steering element. The tunneling-barrier may include a semiconductor or an insulator. Thus, the diode may be a carbon/semiconductor/carbon diode. The semiconductor in the diode may be intrinsic or doped. The semiconductor may be depleted when the diode is under equilibrium conditions. For example, the semiconductor may be lightly doped such that the depletion region extends from one end of the semiconductor region to the other end. The diode may be a carbon/insulator/carbon diode.

Abstract: A Schottky or PN diode is formed where a first cathode portion is an N epitaxial layer that is relatively lightly doped. An N+ buried layer is formed beneath the cathode for conducting the cathode current to a cathode contact. A more highly doped N-well is formed, as a second cathode portion, in the epitaxial layer so that the complete cathode comprises the N-well surrounded by the more lightly doped first cathode portion. An anode covers the upper areas of the first and second cathode portions so both portions conduct current when the diode is forward biased. When the diode is reverse biased, the depletion region in the central N-well will be relatively shallow but substantially planar so will have a relatively high breakdown voltage. The weak link for breakdown voltage will be the curved edge of the deeper depletion region in the lightly doped first cathode portion under the outer edges of the anode. Therefore, the N-well lowers the on-resistance without lowering the breakdown voltage.

Abstract: A mask for use in making a planar PN junction in a semiconductor device includes a central mask opening and a plurality of spaced apart concentric mask openings surrounding the central mask opening. The concentric mask openings each have a width less than a maximum dimension of the central mask opening. The central mask opening can be circular and the concentric mask openings can have a ring-shape. The mask can be used to form openings in a wafer layer for introducing an impurity to dope that wafer layer.

Abstract: A voltage-controlled semiconductor inductor and method is provided. According to various embodiments, the voltage-controlled inductor includes a conductor configured with a number of inductive coils. The inductor also includes a semiconductor material having a contact with at least a portion of at least one of the coils. The semiconductor material is doped to form a diode with a first doped region of first conductivity type, a second doped region of second conductivity type, and a depletion region. A voltage across the diode changes lengths of the first doped region, the second doped region and the depletion region, and adjacent coils in contact with at least one of the doped regions are electrically shorted, thereby varying the inductance of the inductor. In various embodiments, the inductor is electrically connected to a resistor and a capacitor to provide a tunable RLC circuit. Other aspects and embodiments are provided herein.

Abstract: The present invention is directed to a diode with an asymmetric silicon germanium anode and methods of making same. In one illustrative embodiment, the diode includes an anode comprising a P-doped silicon germanium material formed in a semiconducting substrate, an N-doped silicon cathode formed in the semiconducting substrate, a first conductive contact that is conductively coupled to the anode and a second conductive contact that is conductively coupled to the cathode.

Abstract: An ESD protection structure includes a structure to be protected disposed in a semiconductor body. A region of a first conductivity type is disposed within the semiconductor body and a channel is disposed in the semiconductor body and extends through the region of the first conductivity type. A semiconductor of a second conductivity type is disposed within the channel adjacent the region of the first conductivity type such that the region of the first conductivity type and the semiconductor of the second conductivity type form a diode. At least one of the region of the first conductivity type and the semiconductor of the second conductivity type is electrically coupled to the structure to be protected.

Abstract: An active diode with fast turn-on time, low capacitance, and low turn-on resistance may be manufactured without a gate and without a shallow trench isolation region between doped regions of the diode. A short conduction path in the active diode allows a fast turn-on time, and a lack of gate oxide reduces susceptibility of the active diode to extreme voltages. The active diode may be implemented in integrated circuits to prevent and reduce damage from electrostatic discharge (ESD) events. Manufacturing the active diode is accomplished by depositing a salicide block between doped regions of the diode before salicidation. After the salicide layers are formed on the doped regions, the salicide block is removed.

Abstract: A high power density or low forward voltage rectifier which utilizes at least one trench in both the anode and cathode. The trenches are formed in opposing surfaces of the substrate, to increase the junction surface area per unit surface area of the semiconductor die. This structure allows for increased current loads without increased horizontal die space. The increased current handling capability allows for the rectifier to operate at lower forward voltages. Furthermore, the present structure provides for increased substrate usage by up to 30 percent.

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: An anti-parallel diode structure and method of fabrication is presently disclosed. In some embodiments, an anti-parallel diode structure has a semiconductor region comprising a first insulator layer disposed between a first semiconductor layer and a second semiconductor layer. The semiconductor region can be bound on a first side by a first metal material and bound on a second side by a second metal material so that current below a predetermined value is prevented from passing through the semiconductor region and current above the predetermined value passes through the semiconductor region.

Abstract: A photovoltaic device includes a built-in electric field generated by electric dipoles of nanoparticles embedded in a photoconducting host.

Abstract: Structures and methods are provided for nanosecond electrical pulse anneal processes. The method of forming an electrostatic discharge (ESD) N+/P+ structure includes forming an N+ diffusion on a substrate and a P+ diffusion on the substrate. The P+ diffusion is in electrical contact with the N+ diffusion. The method further includes forming a device between the N+ diffusion and the P+ diffusion. A method of annealing a structure or material includes applying an electrical pulse across an electrostatic discharge (ESD) N+/P+ structure for a plurality of nanoseconds.

Abstract: Provided are a schottky diode having an appropriate low breakdown voltage to be used in a radio frequency identification (RFID) tag and a method for fabricating the same. The schottky diode includes a silicon substrate having a structure in which an N-type well is formed on a P-type substrate, an insulating layer surrounding a circumference of the N-type well so as to electrically separate the N-type well from the P-type substrate, an N+ doping layer partly formed in a portion of a region of an upper surface of the N-type well, an N? doping layer partly formed in the other portion of a region of the upper surface of the N-type well, a cathode formed on the N+ doping layer, and an anode formed on the N? doping layer.

Abstract: A bipolar semiconductor device and method are provided. One embodiment provides a bipolar semiconductor device including a first semiconductor region of a first conductivity type having a first doping concentration, a second semiconductor region of a second conductivity type forming a pn-junction with the first semiconductor region, and a plurality of third semiconductor regions of the first conductivity type at least partially arranged in the first semiconductor region and having a doping concentration which is higher than the first doping concentration. Each of the third semiconductor regions is provided with at least one respective junction termination structure.

Abstract: A fast recovery rectifier structure with the combination of Schottky structure to relieve the minority carriers during the forward bias condition for the further reduction of the reverse recovery time during switching in addition to the lifetime killer such as Pt, Au, and/or irradiation. This fast recovery rectifier uses unpolished substrates and thick impurity diffusion for low cost production. A reduced p-n junction structure with a heavily doped film is provided to terminate and shorten the p-n junction space charge region. This reduced p-n junction with less total charge in the p-n junction to further improve the reverse recovery time. This reduced p-n junction can be used alone, with the traditional lifetime killer method, with the Schottky structure and/or with the epitaxial substrate.

Abstract: A geometric diode, method and device applications are described. The geometric diode is produced including a device body formed from an electrically conductive material having an equilibrium mobile charge density, and having a device surface configuration. The material has a charge carrier mean free path with a mean free path length and the device body size is selected based on said the free path length to serve as an electrically conductive path between first and second electrodes delimited by the device surface configuration that is asymmetric with respect to a forward flow of current in a forward direction from the first electrode to the second electrode as compared to a reverse current flow in an reverse direction from the second electrode to the first electrode. A system includes an antenna for receiving electromagnetic radiation coupled with the geometric diode antenna to receive the electromagnetic radiation to produce an electrical response.

Abstract: According to one embodiment, a semiconductor device includes a semiconductor substrate, a semiconductor region, a first and second electrodes. The semiconductor region is provided on the semiconductor substrate via an insulating film. The semiconductor region includes a protection diode. An overvoltage causes breakdown of the protection diode. A PN junction of the protection diode is exposed at an end face of the semiconductor region. A first and second electrodes are provided distally to the exposed end face of the PN junction. The first and second electrodes are connected to the semiconductor region to provide a current to the protection diode.

Abstract: The first layer is located on the first electrode and has the first conductivity type. The second layer is located on the first layer and has the second conductivity type. The third layer is located on the second layer. The second electrode is located on the third layer. The fourth layer is located between the second layer and the third layer, and has the second conductivity type. The third layer includes the first portion and the second portion. The first portion has the second conductivity type and has a peak value of an impurity concentration higher than the peak value of the impurity concentration in the second layer. The second portion has the first conductivity type. The area of the second portion accounts for not less than 20% and not more than 95% of the total area of the first portion and the second portion.

Abstract: A method for manufacturing a semiconductor device includes: an element portion formation step of forming an element portion on a base layer; a delaminating layer formation step of forming a delaminating layer in the base layer; a bonding step of bonding the base layer having the element portion to a substrate; and a separation step of separating and removing a portion of the base layer in the depth direction along the delaminating layer by heating the base layer bonded to the substrate. The method further includes, after the separation step, an ion implantation step of ion-implanting a p-type impurity element in the base layer for adjusting the impurity concentration of a p-type region of the element.

Abstract: A diode is disclosed. One embodiment provides a semiconductor body having a front and a back, opposite the front in a vertical direction of the semiconductor body. The semiconductor body contains, successively in the vertical direction from the back to the front, a heavily n-doped zone, a weakly n-doped zone, a weakly p-doped zone and a heavily p-doped zone. In the vertical direction, the weakly p-doped zone has a thickness of at least 25% and at most 50% of the thickness of the semiconductor body.

Abstract: Microelectronic structures and devices, and method of fabricating a three-dimensional microelectronic structure is provided, comprising passing a first precursor material for a selected three-dimensional microelectronic structure into a reaction chamber at temperatures sufficient to maintain said precursor material in a predominantly gaseous state; maintaining said reaction chamber under sufficient pressures to enhance formation of a first portion of said three-dimensional microelectronic structure; applying an electric field between an electrode and said microelectronic structure at a desired point under conditions whereat said first portion of a selected three-dimensional microelectronic structure is formed from said first precursor material; positionally adjusting either said formed three-dimensional microelectronic structure or said electrode whereby further controlled growth of said three-dimensional microelectronic structure occurs; passing a second precursor material for a selected three-dimensional mi

Abstract: An electronic structure comprising: (a) a first metal layer; (b) a second metal layer; (c) and at least one insulator layer located between the first metal layer and the second metal layer, wherein at least one of the metal layers comprises an amorphous multi-component metallic film. In certain embodiments, the construct is a metal-insulator-metal (MIM) diode.

Abstract: In embodiments of the invention, a method of forming a monolithic three-dimensional memory array is provided, the method including forming a first memory level that includes a plurality of memory cells, each memory cell comprising a plurality of conductors comprising aluminum or copper, and forming a silicon diode in each memory cell, wherein the silicon diode is formed at temperatures compatible with the conductors. The silicon diode may be formed using a hot wire chemical vapor deposition technique, for example. Other aspects are also described.

Abstract: A description is given of a normally on semiconductor component having a drift zone, a drift control zone and a drift control zone dielectric arranged between the drift zone and the drift control zone.

Abstract: A high breakdown voltage semiconductor device, in which a semiconductor layer is formed on a semiconductor substrate across a dielectric layer, includes a drain layer on the semiconductor layer, a buffer layer formed so as to envelop the drain layer, a source layer, separated from the drain layer, and formed so as to surround a periphery thereof, a well layer formed so as to envelop the source layer, and a gate electrode formed across a gate insulating film on the semiconductor layer, wherein the planar shape of the drain layer 113 and buffer layer is a non-continuous or continuous ring.

Abstract: Provided are a multi-purpose magnetic film structure using a spin charge, a method of manufacturing the same, a semiconductor device having the same, and a method of operating the semiconductor memory device. The multi-purpose magnetic film structure includes a lower magnetic film, a tunneling film formed on the lower magnetic film, and an upper magnetic film formed on the tunneling film, wherein the lower and upper magnetic films are ferromagnetic films forming an electrochemical potential difference therebetween when the lower and upper magnetic films have opposite magnetization directions.

Abstract: A switching element for a memory device includes a base layer including a plurality of line-type trenches. First insulation patterns are formed on the base layer excluding the trenches. First diode portions are formed on the bottoms of the trenches in the form of a thin film. Second insulation patterns are formed on the first diode portions and are spaced apart from each other to form holes in the trenches having the first diode portions provided therein. Square pillar-shaped second diode portions are formed in the holes over the first diode portions.

Abstract: Materials, methods, structures and device including the same can provide a semiconductor device such as an LED using an active region corresponding to a non-polar face or surface of III-V semiconductor crystalline material. In some embodiments, an active diode region contains more non-polar III-V material oriented to a non-polar plane than III-V material oriented to a polar plane. In other embodiments, a bottom region contains more non-polar m-plane or a-plane surface area GaN than polar c-plane surface area GaN facing an active region.

Abstract: The present invention generally relates to a circuit structure and a method of manufacturing a circuit, and more specifically to an electrostatic discharge (ESD) circuit with a through wafer via structure and a method of manufacture. An ESD structure includes an ESD active device and at least one through wafer via structure providing a low series resistance path for the ESD active device to a substrate. An apparatus includes an input, at least one power rail and an ESD circuit electrically connected between the input and the at least one power rail, wherein the ESD circuit comprises at least one through wafer via structure providing a low series resistance path to a substrate. A method, includes forming an ESD active device on a substrate, forming a ground plane on a backside of the substrate and forming at least one through wafer via electrically connected to a negative power supply of the ESD active device and the ground plane to provide a low series resistance path to the substrate.

Abstract: A semiconductor device has a semiconductor body with a semiconductor device structure including at least a first electrode and a second electrode. Between the two electrodes, a drift region is arranged, the drift region including charge compensation zones and drift zones arranged substantially parallel to one another. At least one charge carrier storage region which is at least partially free of charge compensation zones is arranged in the semiconductor body.

Abstract: The invention relates to a process for producing a p-n junction in a nanostructure, in which the nanostructure has one or more nanoconstituents made of a semiconductor material with a single type of doping having one conductivity type, characterized in that it includes a step consisting in forming a dielectric element (3, 32, . . . , 3n) embedding the nanostructure over a height h, the dielectric element generating a surface potential capable of inverting the conductivity type over a defined width W of the nanoconstituents(s) thus embedded over the height h.

Abstract: An electrode structure comprises a semiconductor junction comprising an n-type semiconductor layer and a p-type semiconductor layer; a hole exnihilation layer on the p-type semiconductor layer; and a transparent electrode layer on the hole exnihilation layer. The electrode structure further comprises a conductive layer between the hole exnihilation layer and the transparent electrode layer. In the electrode structure, one or more of the hole exnihilation layer, the conductive layer and the transparent electrode layer may be formed by an atomic layer deposition. In the electrode structure, a transparent electrode formed of a degenerated n-type oxide semiconductor does not come in direct contact with a p-type semiconductor, and thus, annihilation or recombination of holes generated in the p-type semiconductor can be reduced, which increases the carrier generation efficiency.

Abstract: A nitride-based semiconductor device includes a diode provided on a semiconductor substrate. The diode contains a first nitride-based semiconductor layer made of non-doped AlXGa1-XN (0?X<1); a second nitride-based semiconductor layer made of non-doped or n-type AlYGa1-YN (0<Y?1, X<Y) having a lattice constant smaller than that of the first nitride-based semiconductor layer; a first electrode formed on the second nitride-based semiconductor layer; a second electrode formed on the second nitride-based semiconductor layer; and an insulating film that covers the second nitride-based semiconductor layer below a peripheral portion of the first electrode. In the diode, a recess structure portion is formed at a position near the peripheral portion of the first electrode on the second nitride-based semiconductor layer, and the first electrode covers the second nitride-based semiconductor layer and at least a part of the insulating film.

Abstract: A multiple layer overvoltage protection device is provided. The method begins by providing a substrate having a first impurity concentration of a first conductivity type to define a mid-region layer. A dopant of a second conductivity type is introduced into the substrate with a second impurity concentration less than the first impurity concentration. An upper base region having a second type of conductivity is formed on the upper surface of the mid-region layer. A lower base region layer having a second type of conductivity is formed on a lower surface of the mid-region layer. A first emitter region having a first type of conductivity is formed on a surface of the upper base region layer. A first metal contact is coupled to the upper base region layer and a second metal contact is coupled to the lower base region layer.

Abstract: In a vertical diode, an N+-type layer, an N?-type layer, and a P+-type layer are stacked in this order on a lower electrode film, and an upper electrode film is provided thereon. The effective impurity concentration of the N?-type layer is lower than the effective impurity concentrations of the N+-type layer and the P+-type layer. At least one of the N+-type layer, the N?-type layer, and the P+-type layer is formed from a small grain size polycrystalline semiconductor whose each crystal grain does not penetrate each layer through its thickness.

Abstract: A diode is provided. The diode includes first and second diffusion layers formed in a substrate, a first metal coupled to the first diffusion layer, and a second metal coupled to the second diffusion layer that has width that is smaller than a width of the second diffusion layer.

Abstract: A positive-intrinsic-negative (PIN)/negative-intrinsic-positive (NIP) diode includes a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate is of a first conductivity. The PIN/NIP diode includes at least one trench formed in the first main surface which defines at least one mesa. The trench extends to a first depth position in the semiconductor substrate. The PIN/NIP diode includes a first anode/cathode layer proximate the first main surface and the sidewalls and the bottom of the trench. The first anode/cathode layer is of a second conductivity opposite to the first conductivity. The PIN/NIP diode includes a second anode/cathode layer proximate the second main surface, a first passivation material lining the trench and a second passivation material lining the mesa. The second anode/cathode layer is the first conductivity.

Abstract: The present invention relates to a method for passivating a semiconductor component having at least one chemosensitive electrode that is blinded by the application of a glass layer. The present invention also relates to a device for detecting at least one substance included in a fluid stream, including at least one semiconductor component acting as a measuring sensor as well as at least one semiconductor component acting as a reference element, the semiconductor components each having a chemosensitive electrode, and the chemosensitive electrode of the semiconductor component acting as the reference element being passivated. For the passivation, a glass layer may be applied at least to the chemosensitive electrode of the semiconductor component acting as reference element.

Abstract: A bipolar semiconductor device and manufacturing method. One embodiment provides a diode structure including a structured emitter coupled to a first metallization is provided. The structured emitter includes a first weakly doped semiconductor region of a first conductivity type which forms a pn-load junction with a weakly doped second semiconductor region of the diode structure. The structured emitter includes at least a highly doped first semiconductor island of the first conductivity type which at least partially surrounds a highly doped second semiconductor island of the second conductivity type.

Abstract: A semiconductor module having one or more silicon carbide diode elements mounted on a switching element is provided in which the temperature rise is reduced by properly disposing each of the diode elements on the switching element, to thereby provide a thermal dissipation path for the respective diode elements. The respective diode elements are arranged on a non-central portion of the switching element, to facilitate dissipation of the heat produced by each of the diode elements, whereby the temperature rise in the semiconductor module is reduced.

Abstract: A diode having a reference voltage electrode, a variable voltage electrode, and a diode material between the electrodes. The diode material is formed of at least one high-K dielectric material and has an asymmetric energy barrier between the reference voltage electrode and the variable voltage electrode, with the energy barrier having a relatively maximum energy barrier level proximate the reference voltage electrode and a minimum energy barrier level proximate the variable voltage electrode.

Abstract: A semiconductor body (1) comprises a connecting lead (21) for contacting a semiconductor area (2). The conductivity S per unit length of the connecting lead (21) changes from a first value SW to a second value S0. The semiconductor area (2) is electrically conductively connected to the connecting lead (21).

Abstract: The invention relates to a high-voltage diode having a specifically optimized switch-off behavior. A soft recovery behavior of the component can be obtained without increasing the forward losses by adjusting in a specific manner the service life of the charge carriers by irradiating only the n+-conducting cathode emitter (6) side or both sides, i.e. the n+-conducting cathode emitter (6) side and the p+-conducting anode emitter (4) side.

Abstract: A semiconductor component in which the active junctions extend perpendicularly to the surface of a semiconductor chip substantially across the entire thickness thereof. The contacts with the regions to be connected are provided by conductive fingers substantially crossing the entire region with which a contact is desired to be established.

Abstract: A metal-insulator diode is disclosed. In one aspect, the metal-insulator diode comprises a first electrode comprising a first metal, a first region comprising a first insulating material, a second region comprising a second insulating material, and a second electrode comprising a second metal. The first region and the second region reside between the first electrode and the second electrode. The second insulating material is doped with nitrogen. Note that the second insulating material may have an interface with either the first electrode or the second electrode.