Abstract: A silicon carbide device is presented that includes a gate electrode disposed over a portion of a silicon carbide substrate as well as a dielectric film disposed over the gate electrode. The device has a contact region disposed near the gate electrode and has a layer disposed over the dielectric film and over the contact region. The layer includes nickel in portions disposed over the dielectric film and includes nickel silicide in portions disposed over the contact region. The nickel silicide layer is configured to provide an ohmic contact to the contact region of the silicon carbide device.

Abstract: Methods for fabricating microelectronic packages and microelectronic packages are provided. In one embodiment, the microelectronic package fabrication method includes producing a molded panel containing a sidewall substrate. The molded panel is singulated to produce a Fan-Out Wafer Level Package core including a molded body having a fan-out region in which the sidewall substrate is embedded. A side connect trace is printed or otherwise formed on a sidewall of the Fan-Out Wafer Level Package core and extends at least partially across the embedded sidewall substrate.

Abstract: A semiconductor substrate has a main surface and formed of single crystal silicon carbide. The main surface includes a central area, which is an area other than the area within 5 mm from the outer circumference. When the central area is divided into square areas of 1 mm×1 mm, in any square area, density of dislocations of which Burgers vector is parallel to <0001> direction is at most 1×105 cm?2. Thus, a silicon carbide semiconductor substrate enabling improved yield of semiconductor devices can be provided.

Abstract: An image adjusting method, a light source module, and an electronic device are provided. The image adjusting method includes the following steps. A first set of light source and a second set of light source of the light source module are driven independently by corresponding driving intensity respectively. An image display command is received. The driving intensity corresponding to the first set of light sources and the second set of light sources respectively are adjusted according to the image display command, wherein a gamut of the first set of light sources is wider than that of the second set of light sources, and luminous efficacy of the second set of light sources is higher than that of the first set of light sources.

Abstract: An interconnect structure and method of making the same. A preferred interconnect structure has a first interconnect including a first dual damascene via and narrow line and a second interconnect at the same level as the first including a second dual damascene via and wider line. The first and second interconnects may have different aspect ratio and may have different line heights while being co-planar with each other. The second line of the second interconnect may abut or partially surround the first line of the first interconnect. The first interconnect includes a refractory metal material as the main conductor, whereas the second interconnect includes a lower resistivity material as its main conductor.

Abstract: A method comprises bonding a first chip on a second chip, depositing a first hard mask layer over a non-bonding side of the first chip, depositing a second hard mask layer over the first hard mask layer, etching a first substrate of the first semiconductor chip using the second hard mask layer as a first etching mask and etching the IMD layers of the first chip and the second chip using the first hard mask layer as a second etching mask.

Abstract: A method for manufacturing semiconductor devices includes following steps. A substrate having a pixel region and a periphery region defined thereon is provided, and at least a transistor is formed in the pixel region. A blocking layer is formed on the substrate, and the blocking layer includes a first opening exposing a portion of the substrate in the pixel region and a second opening exposing a portion of the transistor. A first conductive body is formed in the first opening and a second conductive body is formed in the second opening, respectively. The first conductive body protrudes from the substrate and the second conductive body protrudes from the transistor. A portion of the blocking layer is removed. A first salicide layer is formed on the first conductive body and a second salicide layer is formed on the second conductive body, respectively.

Abstract: Structures, devices and methods are provided for forming nanowires on a substrate. A first protruding structure is formed on a substrate. The first protruding structure is placed in an electrolytic solution. Anodic oxidation is performed using the substrate as part of an anode electrode. One or more nanowires are formed in the protruding structure. The nanowires are surrounded by a first dielectric material formed during the anodic oxidation.

Abstract: An electro-optical device includes a scanning line and a data line intersecting each other, a pixel circuit provided at a position corresponding to an intersection of the scanning line and the data line, and a power supply wiring line that supplies a given potential. The pixel circuit includes a light emitting element and a driving transistor configured to control a current flowing through the light emitting element. A gate electrode of the driving transistor is electrically connected via a first relay electrode to a given node. The first relay electrode is formed in the same layer as the power supply wiring line and the data line. The first relay electrode is surrounded on at least three sides by the power supply wiring line.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming a high-mobility fin field effect transistor (finFET) fin in a silicon semiconductor on insulator (SOI) substrate by trapping crystalline lattice dislocations that occur during epitaxial growth in a recess formed in a semiconductor layer. The crystalline lattice dislocations may remain trapped below a thin isolation layer, thereby reducing device thickness and the need for high-aspect ratio etching and fin formation.

Abstract: An electro-optical device includes a reflective layer, a light emitting element including a light emitting layer formed between an anode and a cathode, and a driving transistor configured to control a current flowing through the light emitting element. In the same layer as the reflective layer, a relay electrode included in a current path from the driving transistor to the anode is formed with a gap between the relay electrode and the reflective layer. A contact electrode electrically connecting the relay electrode and the anode is formed as a light shielding layer that blocks light entering the gap.

Abstract: An opto-electrical device is provided that comprises a cover (10), a barrier structure (20), an opto-electrical structure (30) and a plurality of transverse electrical conductors (40).

Abstract: A micromechanical inertial sensor includes an ASIC element having a processed front side, an MEMS element having a micromechanical sensor structure, and a cap wafer mounted above the micromechanical sensor structure, which sensor structure includes a seismic mass and extends over the entire thickness of the MEMS substrate. The MEMS element is mounted on the processed front side of the ASIC element above a standoff structure and is electrically connected to the ASIC element via through-contacts in the MEMS substrate and in adjacent supports of the standoff structure. A blind hole is formed in the MEMS substrate in the area of the seismic mass, which blind hole is filled with the same electrically conductive material as the through-contacts, the conductive material having a greater density than the MEMS substrate.

Abstract: A light source module and an electronic device are provided. The light source module includes a light guiding plate, at least one light-emitting element and a quantum dot element. The light guiding plate has a light incident surface and a light emitting surface. The at least one light-emitting element is disposed on the light incident surface to provide a first light beam, and includes yttrium aluminum garnet (YAG). The quantum dot element is disposed on the light emitting surface of the light guiding plate, and is configured to transfer part of the first light into a first monochromatic light. White light can be obtained by mixing by the first light and the first monochromatic light.

Abstract: Semiconductor devices, and a method for fabricating the same, include an interlayer dielectric film pattern over a substrate, a first wiring within the interlayer dielectric film pattern and having a first length in a first direction, a second wiring within the interlayer dielectric film pattern and separated from the first wiring, and a spacer contacting the first wiring and the second wiring. The spacer electrically separates the first wiring and the second wiring from each other. The second wiring has a second length different from the first length in the first direction.

Abstract: A bonded semiconductor device comprising a support substrate, a semiconductor device located with respect to one side of the support substrate, a cap substrate overlying the support substrate and the device, a glass frit bond ring between the support substrate and the cap substrate, an electrically conductive ring between the support substrate and the cap substrate. The electrically conductive ring forms an inner ring around the semiconductor device and the glass frit bond ring forms an outer bond ring around the semiconductor device.

Abstract: Techniques are described herein for a dip soldering process which provides a low-profile, low-cost solder bump formation process which may be implemented to promote package thickness scaling (e.g., reduce the overall package thickness). For example, the dip soldering process disclosed herein may enable ultra-thin wafer-level packages (WLP), ultra-thin wafer level quad-flat no-leads (WQFN) packages, or the like.

Abstract: A semiconductor device according to the present invention includes a semiconductor substrate, a surface electrode provided on a front surface of the semiconductor substrate through an insulating film, a via, passing through the semiconductor substrate from a rear surface thereof up to the front surface to reach the surface electrode, having a wall including a flange portion inwardly projecting on a front surface portion of the semiconductor substrate, a via insulating film formed on the wall of the via, and a through-electrode embedded inside the via insulating film and electrically connected to the surface electrode, while the via insulating film has portions having different thickness compensating for a step between the flange portion and the remaining portion of the wall, to planarize a contact surface with the through-electrode.

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: A method of forming a flexible display apparatus includes: forming a flexible substrate on a support substrate; forming a light-emitting diode on the flexible substrate; forming a first encapsulation layer on the light-emitting diode; forming a second encapsulation layer; bonding the first encapsulation layer to the second encapsulation layer using an adhesive layer between the first encapsulation layer and the second encapsulation layer; separating the support substrate from the flexible substrate and cutting the flexible substrate to form the flexible display apparatus; and forming a polarizing plate on the second encapsulation layer.