Abstract: A vertical channel-type 3D semiconductor memory device and a method for manufacturing the same are disclosed. In one aspect, the method includes depositing alternating insulating and electrode layers on a substrate to form a multi-layer film. The method further includes etching the film to the substrate to form through-holes, each of which defines a channel region. The method further includes depositing barrier, storage, and tunnel layers in sequence on inner walls of through-holes to form gate stacks. The method further includes depositing and incompletely filling a channel material on a surface of the tunnel layer of gate stacks to form a hollow channels. The method further includes forming drains in contact hole regions for bit-line connection in top portions of the hollow channels. The method further includes forming sources in contact regions between the through-holes and the substrate in bottom portions of the hollow channels.

Abstract: A method for manufacturing a semiconductor device includes forming an SGT in a semiconductor pillar on a semiconductor substrate and forming a wiring semiconductor layer so as to contact a side surface of an impurity region present in a center portion of the semiconductor pillar or a side surface of a gate conductor layer. A first alloy layer formed in a side surface of the wiring semiconductor layer is directly connected to the impurity region and the gate conductor layer and is connected to an output wiring metal layer through a contact hole formed on an upper surface of a second alloy layer formed in an upper surface and the side surface of the wiring semiconductor layer.

Abstract: One illustrative device disclosed herein includes a substrate fin formed in a substrate comprised of a first semiconductor material, wherein at least a sidewall of the substrate fin is positioned substantially in a <100> crystallographic direction of the crystalline structure of the substrate, a replacement fin structure positioned above the substrate fin, wherein the replacement fin structure is comprised of a semiconductor material that is different from the first semiconductor material, and a gate structure positioned around at least a portion of the replacement fin structure.

Abstract: A semiconductor device includes a fin protruding from a substrate and extending in a first direction, first and second gate structures intersecting the fin, a recess formed in the fin between the first and second gate structures, a device isolation layer which fills the recess, and which has an upper surface protruded outwardly from the fin and disposed to be coplanar with upper surfaces of the first and second gate structures, a liner formed along a side walls of the device isolation layer protruded outwardly from the fin and a source/drain region disposed at both sides of the recess and spaced apart from the device isolation layer.

Abstract: A semiconductor device includes a fin having a first semiconductor material. The fin includes a source/drain (S/D) region and a channel region. The S/D region provides a top surface and two sidewall surfaces. A width of the S/D region is smaller than a width of the channel region. The semiconductor device further includes a semiconductor film over the S/D region and having a doped second semiconductor material. The semiconductor film provides a top surface and two sidewall surfaces that are substantially parallel to the top and two sidewall surfaces of the S/D region respectively. The semiconductor device further includes a metal contact over the top and two sidewall surfaces of the semiconductor film and operable to electrically communicate with the S/D region.

Abstract: A semiconductor device includes a buffer layer on a substrate, the buffer layer having a lattice constant different from that of the substrate, a fin structure upwardly protruding from the buffer layer, a gate electrode crossing over the fin structure, a cladding layer at a side of the fin structure and covering a top surface and sidewalls of the fin structure, and an interfacial layer between the cladding layer and the fin structure, the interfacial layer including a same element as the buffer layer.

Abstract: An organic light emitting diode (OLED) display includes: a thin film transistor on the substrate; a first electrode electrically connected to the thin film transistor; a hole injection layer on the first electrode; an emission layer on the hole injection layer; an electron injection layer on the emission layer; a first intermediate layer on the electron injection layer; and a second electrode on the first intermediate layer.

Abstract: Pass-through 3D interconnects and microelectronic dies and systems of stacked dies that include such interconnects to disable electrical connections are disclosed herein. In one embodiment, a system of stacked dies includes a first microelectronic die having a backside, an interconnect extending through the first die to the backside, an integrated circuit electrically coupled to the interconnect, and a first electrostatic discharge (ESD) device electrically isolated from the interconnect. A second microelectronic die has a front side coupled to the backside of the first die, a metal contact at the front side electrically coupled to the interconnect, and a second ESD device electrically coupled to the metal contact. In another embodiment, the first die further includes a substrate carrying the integrated circuit and the first ESD device, and the interconnect is positioned in the substrate to disable an electrical connection between the first ESD device and the interconnect.

Abstract: A double-diffused metal oxide semiconductor (DMOS) structure is configured as an open drain output driver having electrostatic discharge (ESD) protection and a reverse voltage blocking diode inherent in the structure and without requiring metal connections for the ESD and reverse voltage blocking diode protections.

Abstract: A semiconductor device includes a substrate, an active fin protruding from the substrate, and an asymmetric diamond-shaped source/drain disposed on an upper surface of the active fin. The source/drain includes a first crystal growth portion and a second crystal growth portion sharing a plane with the first crystal growth portion and having a lower surface disposed at a lower level than a lower surface of the first crystal growth portion.

Abstract: A method includes obtaining a photosensor substrate (236) having two opposing major surfaces. One of the two opposing major surfaces includes at least one photosensor row (230) of at least one photosensor element (232, 234), and the obtained photosensor substrate has a thickness equal to or greater than one hundred microns. The method further includes optically coupling a scintillator array (310) to the photosensor substrate. The scintillator array includes at least one complementary scintillator row (224) of at least one complementary scintillator element (226, 228), and the at least one complementary scintillator row is optically coupled to the at least one photosensor row (230) and the at least one complementary scintillator element is optically coupled to the at least one photosensor element.

Abstract: A bipolar junction transistor (BJT), which includes a collector layer, a base layer on the collector layer, an emitter layer on the base layer, and a recess region embedded in the collector layer, is disclosed. A base-collector plane is between the base layer and the collector layer. The recess region is may be below the base-collector plane. Further, the recess region and the base layer are a first type of semiconductor material. By embedding the recess region in the collector layer, the recess region and the collector layer form a first P-N junction, which may provide a point of avalanche for the BJT. Further, the collector layer and the base layer form a second P-N junction. By separating the point of avalanche from the second P-N junction, the BJT may avalanche robustly, thereby reducing the likelihood of avalanche induced failures, particularly in silicon carbide (SiC) BJTs.

Abstract: A semiconductor wafer has a plurality of semiconductor die separated by a peripheral region. A trench is formed in the peripheral region of the wafer. A via is formed on the die. The trench extends to and is continuous with the via. A first conductive layer is deposited in the trench and via to form conductive TSV. The first conductive layer is conformally applied or completely fills the trench and via. The trench has a larger area than the vias which accelerates formation of the first conductive layer. A second conductive layer is deposited over a front surface of the die. The second conductive layer is electrically connected to the first conductive layer. The first and second conductive layers can be formed simultaneously. A portion of a back surface of the wafer is removed to expose the first conductive layer. The die can be electrically interconnected through the TSVs.

Abstract: According to one embodiment, there is disclosed a semiconductor device which has a wiring substrate, a semiconductor element mounted on the wiring substrate, a molding resin which seals the semiconductor element, and a shield layer provided on the molding resin, wherein the molding resin has a marking portion by laser irradiation on a surface, and the shield layer is provided on the molding resin having the marking portion.

Abstract: A module arrangement for power semiconductor devices, including one or more power semiconductor modules, wherein the one or more power semiconductor modules include a substrate with a first surface and a second surface being arranged opposite to the first surface, wherein the substrate is at least partially electrically insulating, wherein a conductive structure is arranged at the first surface of the substrate, wherein at least one power semiconductor device is arranged on the conductive structure and electrically connected thereto, wherein the one or more modules includes an inner volume for receiving the at least one power semiconductor device which volume is hermetically sealed from its surrounding by a module enclosure, wherein the module arrangement includes an arrangement enclosure at least partly defining a volume for receiving the one or more modules, and wherein the arrangement enclosure seals covers the volume.

Abstract: A semiconductor device has a small area and constitutes a CMOS 3-input NAND circuit by using surrounding gate transistors (SGTs) that are vertical transistors. In a 3-input NAND circuit including six MOS transistors arranged in a line, the MOS transistors constituting the NAND circuit have the following configuration. Planar silicon layers are disposed on a substrate. The drain, gate, and source of the MOS transistors are arranged in a vertical direction, and the gate surrounds a silicon pillar. The planer silicon layers include a first active region having a first conductivity type and a second active region having a second conductivity type. The first and second active regions are connected to each other via a silicide layer disposed on surfaces of the planar silicon layers. In this way, a semiconductor device constituting a NAND circuit with a small area is provided.

Abstract: Various examples are provided for ambipolar vertical field effect transistors (VFETs). In one example, among others, an ambipolar VFET includes a gate layer; a source layer that is electrically percolating and perforated; a dielectric layer; a drain layer; and a semiconducting channel layer. The semiconducting channel layer is in contact with at least a portion of the source layer and at least a portion of the dielectric layer and the source layer and the semiconducting channel layer form a gate voltage tunable charge injection barrier. Another example includes an ambipolar vertical field effect transistor including a dielectric surface treatment layer. The semiconducting channel layer is in contact with at least a portion of the source layer and at least a portion of the dielectric surface treatment layer and where the source layer and the semiconducting channel layer form a gate voltage tunable charge injection barrier.

Abstract: An optoelectronic device comprising a mesa structure including: a first and a second semiconductor portions forming a p-n junction, a first electrode electrically connected to the first portion which is arranged between the second portion and the first electrode, the device further comprising: a second electrode electrically connected to the second portion, an element able to ionize dopants of the first and/or second semiconductor portion through generating an electric field in the first and/or second semiconductor portion and overlaying at least one part of the side flanks of at least one part of the first and/or second semiconductor portion and of at least one part of a space charge zone formed by the first and second semiconductor portions, upper faces of the first electrode and of the second electrode form a substantially planar continuous surface.

Abstract: A MOS varactor includes a first N-type junction region and a second N-type junction region spaced apart from each other by a channel region, a gate insulation layer disposed on the channel region, a gate electrode disposed on the gate insulation layer, and an N-type well region including the channel region and surrounding the first and second N-type junction regions. The N-type well region exhibits a maximum impurity concentration in the channel region.

Abstract: Provided are single photon devices, single photon emitting and transferring apparatuses, and methods of manufacturing and operating the single photon devices. The single photon device includes a carrier transport layer disposed on a conductive substrate and at least one quantum dot disposed on the carrier transport layer. A single photon emitting and transferring apparatus includes a single photon device, an element that injects a single charge into the single photon device described above, a light collecting unit that collects light emitted from the single photon device, and a light transfer system that transmits light collected by the light collecting unit to the outside.