Abstract: A semiconductor device has a semiconductor die with an encapsulant deposited over the semiconductor die. A first insulating layer having high tensile strength and elongation is formed over the semiconductor die and encapsulant. A first portion of the first insulating layer is removed by a first laser direct ablation to form a plurality of openings in the first insulating layer. The openings extend partially through the first insulating layer or into the encapsulant. A second portion of the first insulating layer is removed by a second laser direct ablation to form a plurality of trenches in the first insulating layer. A conductive layer is formed in the openings and trenches of the first insulating layer. A second insulating layer is formed over the conductive layer. A portion of the second insulating layer is removed by a third laser direct ablation. Bumps are formed over the conductive layer.

Abstract: The present invention relates to resistive memory devices incorporating therein vertical selection transistors and methods for making the same. A memory device comprises a semiconductor substrate having a first type conductivity and a plurality of parallel trenches therein; a plurality of parallel common source lines having a second type conductivity opposite to the first type conductivity formed in the trench bottoms; a plurality of parallel gate electrodes formed on the trench sidewalls with a gate dielectric layer interposed therebetween, the gate electrodes being lower in height than the trench sidewalls; and a plurality of drain regions having the second type conductivity formed in top regions of the trench sidewalls, at least two of the drain regions being formed in each of the trench sidewalls and sharing a respective common channel formed in the each of the trench sidewalls and a respective one of the source lines.

Abstract: Resistive memory having confined filament formation is described herein. One or more method embodiments include forming an opening in a stack having a silicon material and an oxide material on the silicon material, and forming an oxide material in the opening adjacent the silicon material, wherein the oxide material formed in the opening confines filament formation in the resistive memory cell to an area enclosed by the oxide material formed in the opening.

Abstract: Disclosed is a semiconductor structure incorporating a contact sidewall spacer with a self-aligned airgap and a method of forming the semiconductor structure. The structure comprises a semiconductor device (e.g., a two-terminal device, such as a PN junction diode or Schottky diode, or a three-terminal device, such as a field effect transistor (FET), a bipolar junction transistor (BJT), etc.) and a dielectric layer that covers the semiconductor device. A contact extends vertically through the dielectric layer to a terminal of the semiconductor device (e.g., in the case of a FET, to a source/drain region of the FET). A contact sidewall spacer is positioned on the contact sidewall and incorporates an airgap. Since air has a lower dielectric constant than other typically used dielectric spacer or interlayer dielectric materials, the contact size can be increased for reduced parasitic resistance while minimizing corresponding increases in parasitic capacitance or the probability of shorts.

Abstract: The invention relates to an organic electroluminescent device (1) comprising a substrate (2), at least one electroluminescent layer stack on top of the substrate (2) with at least a substrate electrode (3), a counter electrode (5) and at least one organic electroluminescent layer (4) arranged between substrate electrode (2) and counter electrode (5), and a short prevention layer (6) covering the counter electrode (5) establishing a double layer (DL) with a tensile stress (TS) induced by the short prevention layer (5), and an electrically isolating layer (8) at least partly covering the short prevention layer (6), wherein the electrically isolating layer (8) is suitable to partially dissolve the organic layer (4) in the vicinity of a defect (7) within the electroluminescent layer stack and the tensile stress (TS) induced by the short prevention layer (6) is suitable to roll up (10) the double layer (DL) adjacent to the defect (7) after deposition of the electrically isolating layer (8).

Abstract: A photoelectric conversion portion, a charge holding portion, a transfer portion, and a sense node are formed in a P-type well. The charge holding portion is configured to include an N-type semiconductor region, which is a first semiconductor region holding charges in a portion different from the photoelectric conversion portion. A P-type semiconductor region having a higher concentration than the P-type well is disposed under the N-type semiconductor region.

Abstract: A high breakdown voltage diode of the present embodiment includes a first conductive semiconductor substrate, a drift layer formed on the first conductive semiconductor substrate and formed of a first conductive semiconductor, a buffer layer formed on the drift layer and formed of a second conductive semiconductor, a second conductive high concentration semiconductor region formed at an upper portion of the buffer layer, a mesa termination unit formed on an end region of a semiconductor apparatus to relax an electric field of the end region when reverse bias is applied between the semiconductor substrate and the buffer layer, and an electric field relaxation region formed at the mesa termination unit and formed of a second conductive semiconductor. A breakdown voltage of a high breakdown voltage diode, in which a pn junction is provided to a semiconductor layer, is increased, and a process yield is improved.

Abstract: A light-emitting element includes: an anode; a cathode; a light-emitting layer which is provided between the anode and the cathode and emits light as the anode and the cathode are electrically connected to each other; and an organic layer which is provided between the anode and the light-emitting layer to come in contact with both layers. The organic layer has a first function of transporting holes and a second function of preventing electrons infiltrating from the light-emitting layer from staying in the organic layer.

Abstract: A lead frame for assembling a semiconductor device has a die pad surrounded by lead fingers. Each of the lead fingers has a proximal end close to but spaced from an edge of the die pad and a distal end farther from the die pad. A semiconductor die is attached to a surface of the die pad. The die has die bonding pads on its upper surface that are electrically connected to the proximal ends of the lead fingers with bond wires. An encapsulation material covers the bond wires, semiconductor die and the proximal ends of the lead fingers. Prior to assembly, hot spots of the die are determined and the lead fingers closest to the hot spots are selected to project closer to the die than the other lead fingers. These longer lead fingers assist in dissipating the heat at the die hot spot.

Abstract: A solid-state image pickup device includes a photoelectric conversion portion, a charge holding portion configured to include a first-conductivity-type first semiconductor region, and a transfer portion configured to include a transfer gate electrode that controls a potential between the charge holding portion and a sense node. The charge holding portion includes a control electrode. A second-conductivity-type second semiconductor region is disposed on a surface of a semiconductor region between the control electrode and the transfer gate electrode. A first-conductivity-type third semiconductor region is disposed under the second semiconductor region. The third semiconductor region is disposed at a deeper position than the first semiconductor region.

Abstract: Disclosed is a semiconductor device including: a semiconductor substrate; a field effect transistor formed on the semiconductor substrate; and a diode forming area adjacent to a forming area of the field effect transistor, wherein the diode forming area is insulated from the forming area of the field effect transistor on the semiconductor substrate, the diode forming area includes an anode electrode and a cathode electrode arranged side by side in a multi-finger shape, and the anode electrode and the cathode electrode are formed in a direction different from directions of a gate electrode, a source electrode, and a drain electrode of the field effect transistor arranged side by side in a multi-finger shape.

Abstract: A fin resistor and method of fabrication are disclosed. The fin resistor comprises a plurality of fins arranged in a linear pattern with an alternating pattern of epitaxial regions. An anneal diffuses dopants from the epitaxial regions into the fins. Contacts are connected to endpoint epitaxial regions to allow the resistor to be connected to more complex integrated circuits.

Abstract: There is provided a semiconductor light-emitting element which has an electrode structural body including a connection electrode and a wiring electrode connected to the connection electrode, the wiring electrode stretching along a surface of a semiconductor layered body while being in partial contact with the surface of the semiconductor layered body exposed from an opening formed on the insulation layer. The area of a contact region between the wiring electrode and the semiconductor layered body increases, from a connection end which is connected to the connection electrode, along a direction in which the wiring electrode stretches.

Abstract: A semiconductor device has a semiconductor die and first insulating layer formed over the semiconductor die. A plurality of first micro-vias can be formed in the first insulating layer. A conductive layer is formed in the first micro-openings and over the first insulating layer. A second insulating layer is formed over the first insulating layer and conductive layer. A portion of the second insulating layer is removed to expose the conductive layer and form a plurality of second micro-openings in the second insulating layer over the conductive layer. The second micro-openings can be micro-vias, micro-via ring, or micro-via slots. Removing the portion of the second insulating layer leaves an island of the second insulating layer over the conductive layer. A bump is formed over the conductive layer. A third insulating layer is formed in the second micro-openings over the bump. The second micro-openings provide stress relief.

Abstract: According to one embodiment, a nonvolatile semiconductor memory includes a semiconductor layer, a first insulating layer on the semiconductor layer, a charge storage layer on the first insulating layer, a second insulating layer on the charge storage layer, and a control gate electrode on the second insulating layer. The second insulating layer comprises a stacked structure provided in order of a first lanthanum aluminate layer, a lanthanum aluminum silicate layer and a second lanthanum aluminate layer from the charge storage layer side to the control gate electrode side.

Abstract: In accordance with an embodiment, a semiconductor device includes a substrate, a line-and-space structure, a first film and a second film. The line-and-space structure includes line patterns arranged on the substrate parallel to one another at a predetermined distance. The first film is formed on side surfaces and bottom surfaces of the line patterns by an insulating film material. The second film is formed on the line-and-space structure across a space between the line patterns by a material showing low wettability to the first film. Space between the line patterns includes an air gap in which at least a bottom surface of the first film is totally exposed.

Abstract: A method of manufacturing a phase change memory device includes forming a lower electrode layer pattern and an insulating interlayer covering the lower electrode layer pattern, forming a first opening in the insulating interlayer to expose the lower electrode layer pattern, forming an oxide layer pattern on the sidewall of the first opening and a lower electrode under the oxide layer pattern by partially removing the oxide layer and the lower electrode layer pattern, forming an insulation layer filling a remaining portion of the first opening, removing the oxide layer pattern by a wet etching process to form a second opening, and forming a phase change material pattern on the lower electrode such that the phase change material pattern fills the second opening.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a substrate having a surface that is defined by a first axis and a second axis perpendicular to the first axis; and a capacitor disposed on the substrate, the capacitor having an anode component that includes a plurality of first conductive features and a cathode component that includes a plurality of second conductive features. The first conductive features and the second conductive features each include two metal lines extending along the first axis. At least one metal via extending along a third axis that is perpendicular to the surface of the substrate and interconnecting the two metal lines. The first conductive features are interdigitated with the second conductive features along both the second axis and the third axis.

Abstract: Some embodiments include methods of forming memory cells. An opening is formed over a first conductive structure to expose an upper surface of the first conductive structure. The opening has a bottom level with a bottom width. The opening has a second level over the bottom level, with the second level having a second width which is greater than the bottom width. The bottom level of the opening is filled with a first portion of a multi-portion programmable material, and the second level is lined with the first portion. The lined second level is filled with a second portion of the multi-portion programmable material. A second conductive structure is formed over the second portion. Some embodiments include memory cells.

Abstract: A resistive memory device having an in-situ nitride initiation layer is disclosed. The nitride initiation layer is formed above the first electrode, and the metal oxide switching layer is formed above the nitride initiation layer to prevent oxidation of the first electrode. The nitride initiation layer may be a metal nitride layer that is formed by atomic layer deposition in the same chamber in which the metal oxide switching layer is formed. The nitride initiation layer and metal oxide switching layer may alternatively be formed in a chemical vapor deposition (CVD) chamber or a physical vapor deposition (PVD) chamber.