Abstract: A semiconductor memory device according to an embodiment comprises a semiconductor layer, a variable resistance layer, a sidewall layer, and a buried layer. The semiconductor layer functions as a rectifying device. The variable resistance layer is provided above or below the semiconductor layer and reversibly changes its resistance. The sidewall layer is in contact with a sidewall of the semiconductor layer. The buried layer is embedded in the sidewall layer and is made of material different from that of the sidewall layer. These configurations may adjust the electrical characteristics of the rectifying device to any value.

Abstract: A semiconductor device including a semiconductor layer of a first conductivity type in a cell region, a first base layer of a second conductivity type on the semiconductor layer in the cell region; a second base layer of the second conductivity type on the semiconductor layer in an intermediate region; a conductive region of a first conductivity type in the first base layer; a gate electrode on a channel region placed between the conductive region and the semiconductor layer; a first electrode connected to the first and second base layers; a second electrode connected to the semiconductor layer; and a gate pad on the semiconductor layer via an insulating film in a pad region and connected to the gate electrode, an impurity concentration gradation in the gate pad side of the second base layer has a gentler VLD structure than an impurity concentration gradation in the first base layer.

Abstract: A semiconductor device has a substrate with a first conductive layer over a surface of the substrate and a plurality of cavities exposing the first conductive layer. A first semiconductor die having conductive TSV is mounted into the cavities of the substrate. A first insulating layer is formed over the substrate and first semiconductor die and extends into the cavities to embed the first semiconductor die within the substrate. A portion of the first insulating layer is removed to expose the conductive TSV. A second conductive layer is formed over the conductive TSV. A portion of the first conductive layer is removed to form electrically common or electrically isolated conductive segments of the first conductive layer. A second insulating layer is formed over the substrate and conductive segments of the first conductive layer. A second semiconductor die is mounted over the substrate electrically connected to the second conductive layer.

Abstract: A methodology for forming a self-aligned contact (SAC) that exhibits reduced likelihood of a contact-to-gate short circuit failure and the resulting device are disclosed. Embodiments may include forming a replacement metal gate, with spacers at opposite sides thereof, on a substrate, forming a recess in an upper surface of the spacers along outer edges of the replacement metal gate, and forming an aluminum nitride (AlN) cap over the metal gate and in the recess.

Abstract: A sensor element is described that includes at least one semiconductor component having a gas-sensitive layer which is attached to a substrate by the flip-chip method, the gas-sensitive layer facing the substrate and a supply arrangement being provided to supply a gas to be examined to the gas-sensitive layer. The semiconductor component is enclosed in a casing. Also described is a method for manufacturing the sensor element, in which a semiconductor component having a gas-sensitive layer is attached by the flip-chip method to a substrate in such a way that the gas-sensitive layer faces the substrate. After that, the casing is applied by a plasma sputtering method, in particular an atmospheric plasma sputtering method. Finally, a use of the sensor element in the exhaust system of an internal combustion engine is also described.

Abstract: A light emitting diode (LED) carrier assembly includes an LED die mounted on a silicon submount, a middle layer that is thermally conductive and electrically isolating disposed below the silicon submount, and a printed circuit board (PCB) disposed below the middle layer. The middle layer is bonded with the silicon submount and the PCB.

Abstract: A semiconductor device (semiconductor module) includes a circuit board (module board) and a semiconductor element mounted on the circuit board. A shielding layer that blocks electromagnetic waves is disposed on the upper surface of the semiconductor element, and an antenna element is disposed over the shielding layer. The semiconductor element and the antenna element are electrically connected to each other by a connecting portion. This structure enables the semiconductor device to be reduced in size and to have both an electromagnetic-wave blocking function and an antenna function.

Abstract: The present disclosure involves an apparatus. The apparatus includes a substrate having a front side a back side opposite the front side. The substrate includes a plurality of openings formed from the back side of the substrate. The openings collectively define a pattern on the back side of the substrate from a planar view. In some embodiments, the substrate is a silicon substrate or a silicon carbide substrate. Portions of the silicon substrate vertically aligned with the openings have vertical dimensions that vary from about 100 microns to about 300 microns. A III-V group compound layer is formed over the front side of the silicon substrate. The III-V group compound layer is a component of one of: a light-emitting diode (LED), a laser diode (LD), and a high-electron mobility transistor (HEMT).

Abstract: Semiconductor assemblies, structures, and methods of fabrication are disclosed. A coating is formed on an electrically conductive pillar. The coating, which may be formed from at least one of a silane material and an organic solderability protectant material, may bond to a conductive material of the electrically conductive pillar and, optionally, to other metallic materials of the electrically conductive pillar. The coating may also bond to substrate passivation material, if present, or to otherwise-exposed surfaces of a substrate and a bond pad. The coating may be selectively formed on the conductive material. Material may not be removed from the coating after formation thereof and before reflow of the solder for die attach. The coating may isolate at least the conductive material from solder, inhibiting solder wicking or slumping along the conductive material and may enhance adhesion between the resulting bonded conductive element and an underfill material.

Abstract: According to one embodiment, a semiconductor device includes a first, a second, a third, a fourth, and a fifth semiconductor region, an insulating film, a control electrode, and a first and a second electrode. The first, the second, the third, the fourth and the fifth semiconductor region include silicon carbide. The first semiconductor region has a first impurity concentration, and has a first portion. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region is provided on the second semiconductor region. The fourth semiconductor region is provided between the first portion and the second semiconductor region. The fourth semiconductor region is provided between the first portion and the third semiconductor region. The fifth semiconductor region includes a first region provided between the first portion and the second semiconductor region, and has a second impurity concentration higher than the first impurity concentration.

Abstract: A variable resistance memory device includes active regions defined by an isolation layer in a semiconductor substrate, trenches in the semiconductor substrate, which extend in a direction crossing the active regions, junction regions formed in the active regions on both sides of the trenches, and variable resistance patterns interposed between the word lines and the junction regions.

Abstract: Integrated circuits and processes for forming integrated circuits are provided. An exemplary process for forming an integrated circuit includes providing a substrate including an oxide layer and a protecting layer disposed over the oxide layer. A recess is etched through the protecting layer and at least partially into the oxide layer. A barrier material is deposited in the recess to form a barrier layer over the oxide layer and protecting layer in the recess. Electrically-conductive material is deposited over the barrier layer in the recess to form the embedded electrical interconnect. The embedded electrical interconnect and barrier layer are recessed to an interconnect recess depth and a barrier recess depth, respectively, within the substrate. At least a portion of the protecting layer remains over the oxide layer after recessing the barrier layer and is removed after recessing the barrier layer.

Abstract: A microelectronic assembly can include first, second and third stacked substantially planar elements, e.g., of dielectric or semiconductor material, and which may have a CTE of less than 10 ppm/° C. The assembly may be a microelectronic package and may incorporate active semiconductor devices in one, two or more of the first, second or third elements to function cooperatively as a system-in-a-package. In one example, an electrically conductive element having at least a portion having a thickness less than 10 microns, may be formed by plating, and may electrically connect two or more of the first, second or third elements. The conductive element may entirely underlie a surface of another one of the substantially planar elements.

Abstract: A method for fabricating a dynamic random access memory (DRAM) capacitor stack is disclosed wherein the stack includes a first electrode, a dielectric layer, and a second electrode. The first electrode is formed from a conductive binary metal. A dielectric layer is formed over the first electrode. The dielectric layer is subjected to a milliseconds anneal process that serves to crystallize the dielectric material and decrease the concentration of oxygen vacancies.

Abstract: A light-emitting device comprises a substrate, and a light-emitting structure formed on the substrate. The light-emitting structure comprises a first active layer emitting the light with a first wavelength, and a second active layer emitting the light with a second wavelength. The light-emitting structure is formed by the first active layer and the second active layer stacked alternately.

Abstract: A semiconductor chip is mounted on a first surface of an interconnect substrate, and has a multilayer interconnect layer. A first inductor is formed over the multilayer interconnect layer, and a wiring axis direction thereof is directed in a horizontal direction to the interconnect substrate. A second inductor is formed on the multilayer interconnect layer, and a wiring axis direction thereof is directed in the horizontal direction to the interconnect substrate. The second inductor is opposite to the first inductor. A sealing resin seals at least the first surface of the interconnect substrate and the semiconductor chip. A groove is formed over the whole area of a portion that is positioned between the at least first inductor and the second inductor of a boundary surface of the multilayer interconnect layer and the sealing resin.

Abstract: Graphene transistor devices and methods of their fabrication are disclosed. In accordance with one method, a resist is deposited to pattern a gate structure area over a graphene channel on a substrate. In addition, gate dielectric material and gate electrode material are deposited over the graphene channel and the resist. Further, the resist and the electrode and dielectric materials that are disposed above the resist are lifted-off to form a gate structure including a gate electrode and a gate dielectric spacer and to expose portions of the graphene channel that are adjacent to the gate structure. Additionally, source and drain electrodes are formed over the exposed portions of the graphene channel.

Abstract: Graphene transistor devices and methods of their fabrication are disclosed. One such graphene transistor device includes source and drain electrodes and a gate structure including a dielectric sidewall spacer that is disposed between the source and drain electrodes. The device further includes a graphene layer that is adjacent to at least one of the source and drain electrodes, where an interface between the source/drain electrode(s) and the graphene layer maintains a consistent degree of electrical conductivity throughout the interface.

Abstract: An organic light emitting diode (OLED) display includes: a substrate including a first area and a second area; a first electrode at the first area of the substrate, and a first electrode at the second area of the substrate; a reflective electrode on the first electrode at the first area; a barrier rib on the substrate, the barrier rib having openings exposing the reflective electrode and the first electrode at the second area; an organic emission layer on the reflective electrode and the first electrode at the second area; a second electrode on the organic emission layer; and a reflective layer on the second electrode at the second area.

Abstract: In one aspect, a back plane for a flat panel display apparatus include: a substrate; a source electrode and a drain electrode formed on the substrate; a capacitor bottom electrode formed on a same layer as the source/drain electrodes; an active layer formed on the substrate in correspondence to the source electrode and the drain electrode; a blocking layer interposed between the source electrode and the drain electrode and the active layer; a first insulation layer formed on the substrate to cover the active layer; a gate electrode formed on the first insulation layer in correspondence to the active layer; a capacitor top electrode formed on a same layer as the gate electrode in correspondence to the capacitor bottom electrode; and a second insulation layer formed on the first insulation layer to cover the gate electrode and the capacitor top electrode is provided.