Abstract: Some embodiments of the present disclosure provide a back side illuminated (BSI) image sensor. BSI image sensor includes a semiconductive substrate, a dielectric layer over the semiconductive substrate, and a pixel region. The pixel region includes a transistor disposed at a front side of the semiconductive substrate. The transistor includes a gate structure and at least a source region or a drain region. The transistor is coupled to a contact disposed in the dielectric layer. An oxide layer covers the gate structure and at least the source region or the drain region. A nitride layer covers the gate structure and at least the source region or the drain region. A color filter is disposed at a back side of the semiconductive substrate.

Abstract: A method of forming a barrier on both the sidewalls and bottom of a via and the resulting device are provided. Embodiments include forming a metal line in a substrate; forming a Si-based insulating layer over the metal line and the substrate; forming a via in the Si-based insulating layer down to the metal line; forming a dual-layer Mn/MnN on sidewalls and a bottom surface of the via; and filling the via with metal.

Abstract: An organic light emitting diode includes a first electrode layer disposed on a base substrate, a second electrode layer disposed on the first electrode layer and facing the first electrode layer, an emitting layer disposed between the first electrode layer and the second electrode layer, a hole transport region disposed between the emitting layer and the first electrode layer, an auxiliary layer disposed between the hole transport region and the emitting layer, the auxiliary layer including a first material and a second material, and an electron transport region disposed between the emitting layer and the second electrode layer, in which a lowest unoccupied molecular orbital (LUMO) energy level of the first material is higher than a LUMO energy level of the emitting layer, and a LUMO energy level of the second material is lower than the LUMO energy level of the emitting layer.

Abstract: A method for fabricating memory device is disclosed. The method includes the steps of: providing a substrate having a tunnel oxide layer on the substrate, a first electrode layer on the tunnel oxide layer, an oxide-nitride-oxide (ONO) stack on the first electrode layer, and a second electrode layer on the ONO stack, and then removing part of the second electrode layer, part of the ONO stack, and part of the first electrode layer so that the tunnel oxide layer is not exposed.

Abstract: An organic light emitting display apparatus includes: a first pixel electrode and a second pixel electrode on a substrate and spaced apart from each other, each of the first pixel electrode and the second pixel electrode including a reflective layer; a pixel definition layer extending between and overlapping adjacent edges of the first pixel electrode and the second pixel electrode; a first intermediate layer and a second intermediate layer respectively on the first pixel electrode and the second pixel electrode; and an opposite electrode on the first intermediate layer, the second intermediate layer and the pixel definition layer and including a reflective layer.

Abstract: In an embodiment of the invention, a semiconductor device includes a first region having a first doping type, a channel region having the first doping type disposed in the first region, and a retrograde well having a second doping type. The second doping type is opposite to the first doping type. The retrograde well has a shallower layer with a first peak doping and a deeper layer with a second peak doping higher than the first peak doping. The device further includes a drain region having the second doping type over the retrograde well. An extended drain region is disposed in the retrograde well, and couples the channel region with the drain region. An isolation region is disposed between a gate overlap region of the extended drain region and the drain region. A length of the drain region is greater than a depth of the isolation region.

Abstract: A method for forming a semiconductor structure includes forming a first metal layer over a first dielectric layer, forming a first graphene layer on at least one major surface of the first metal layer, and forming a second dielectric layer over the first metal layer and the first graphene layer. The method further includes forming an opening in the second dielectric layer which exposes the first metal layer, forming a second metal layer over the second dielectric layer and within the opening, and forming a second graphene layer on at least one major surface of the second metal layer, wherein the second graphene layer is also formed within the opening.

Abstract: To realize a high-performance liquid crystal display device or light-emitting element using a plastic film. A CPU is formed over a first glass substrate and then, separated from the first substrate. A pixel portion having a light-emitting element is formed over a second glass substrate, and then, separated from the second substrate. The both are bonded to each other. Therefore, high integration can be achieved. Further, in this case, the separated layer including the CPU serves also as a sealing layer of the light-emitting element.

Abstract: Provided are approaches for forming gate and source/drain (S/D) contacts. Specifically, a gate contact opening is formed over at least one of a set of gate structures, a set of S/D contact openings is formed over fins of the semiconductor device, and a metal material is deposited over the semiconductor device to form a gate contact within the gate contact opening and a set of S/D contacts within the set of S/D contact openings. In one approach, nitride remains between the gate contact and at least one of the S/D contacts. In another approach, the device includes merged gate and S/D contacts. This approach provides selective etching to partition areas where oxide will be further removed selectively to nitride to create cavities to metallize and create contact to the S/D, while isolation areas between contact areas are enclosed in nitride and do not get removed during the oxide etch.

Abstract: A method of applying a fluorescent material to a surface includes providing a substrate, providing a semiconductor light-emitting stack on the substrate, bonding the substrate to the semiconductor light-emitting stack, and overlaying top and side surfaces of the semiconductor light-emitting stack with the fluorescent material, wherein the fluorescent material contains no binding material.

Abstract: A microelectronic semiconductor package includes first and second microelectronic elements and a substrate positioned between them. Each of the microelectronic elements has active and passive surfaces, first edges bounding the surfaces in a first lateral direction and second edges bounding the surfaces in a second lateral direction transverse to the first lateral direction. The first microelectronic overlies the second microelectronic element and the active surface of the first microelectronic element faces toward the passive surface of the second microelectronic element. Each of the first edges of the first microelectronic element are disposed beyond each of the adjacent first edges of the second microelectronic element. Each of the second edges of the second microelectronic element are disposed beyond each of adjacent second edges of the first microelectronic element.

Abstract: Methods and devices including the formation of a layer of nanowires on wiring line traces are described. One device comprises a first dielectric layer and a plurality of traces on the first dielectric layer, the traces comprising Cu. The traces include a layer of ZnO nanowires positioned thereon. A second dielectric layer is positioned on the first dielectric layer and on the traces, wherein the second dielectric layer is in direct contact with the ZnO nanowires. Other embodiments are described and claimed.

Abstract: A method for manufacturing a semiconductor structure includes at least following steps. A device layer is formed on a first semiconductor substrate. The device layer is separated from the first semiconductor substrate. A dielectric layer is formed on a second semiconductor substrate. The device layer is bonded onto the dielectric layer.

Abstract: A method of manufacturing is provided that includes applying a thermal interface tape to a side of a semiconductor wafer that includes at least one semiconductor chip. The thermal interface material tape is positioned on the at least one semiconductor chip. The at least one semiconductor chip is singulated from the semiconductor wafer with at least a portion of the thermal interface tape still attached to the semiconductor chip.

Abstract: A power semiconductor device is disclosed. The power semiconductor device includes a source region in a body region, a gate trench adjacent to the source region, and a source trench electrically coupled to the source region. The source trench includes a source trench conductive filler surrounded by a source trench dielectric liner, and extends into a drift region. The power semiconductor device includes a source trench implant below the source trench and a drain region below the drift region, where the source trench implant has a conductivity type opposite that of the drift region. The power semiconductor device may also include a termination trench adjacent to the source trench, where the termination trench includes a termination trench conductive filler surrounded by a termination trench dielectric liner. The power semiconductor device may also include a termination trench implant below the termination trench.

Abstract: An array substrate, a method for repairing broken line of the array substrate, and a display device are provided. The array substrate comprises: a gate line (2) and a data line (5) intersecting with each other to define a plurality of pixel regions arranged in a matrix form; a thin film transistor (11a) disposed in the vicinity of an intersection of the gate line (2) and the data line (5), a gate electrode (2?) of the thin film transistor (11a) being connected to the gate line (2), and a source electrode of the thin film transistor (11a) being connected to the data line (5); a common electrode (8) and a pixel electrode (6) disposed in each pixel region.

Abstract: A method of forming a device may include: forming an opening through a dielectric layer and an underlying etching stop layer to expose a metal line. The method may further include the step of catalytically growing a graphene layer on an exposed surface of the metal line, and depositing an amorphous carbon layer on sidewalls of the opening. The steps of catalytically growing the graphene layer and depositing the amorphous carbon layer may be performed simultaneously.

Abstract: A memory device comprises a first conductive stripe, a first memory layer, a first conductive pillar, a first dielectric layer and a first conductive plug. The first conductive strip extends along a first direction. The first memory layer extends along a second direction adjacent to and overlapping with the first conductive stripe to define a first memory area thereon. The first conductive pillar extends along the second direction and overlapping with the first memory area. The first dielectric layer extends along the second direction adjacent to the first conductive stripe, the first memory layer and the first conductive pillar. The first conductive plus extends along the second direction and at least overlaps with a portion of the first conductive stripe, wherein the first conductive plus is electrically insulated from the first conductive stripe, the first memory layer and the first conductive pillar by the first dielectric layer.

Abstract: A semiconductor device includes a first chip coupled to an electrical insulator, and a sintered heat conducting layer disposed between the electrical insulator and the first chip.

Abstract: A metal strap is formed in a middle-of-line (MOL) process for communication between an eDRAM and a FinFET. An oxide is deposited in a trench over the eDRAM to prevent development of an epitaxial film prior to formation of the metal strap. The result is an epiless eDRAM strap in a FinFET.