Abstract: Methods, apparatus, and systems for forming a semiconductor substrate comprising a well region containing a first impurity; forming a gate on the semiconductor substrate above the well region; implanting a second impurity, of a type opposite the first impurity, in the well region on each side of the gate and to a depth above a bottom of the well region, to form two second impurity regions each having a first concentration; removing an upper portion of each second impurity region, to yield two source/drain (S/D) cavities above two depletion regions; and growing epitaxially a doped S/D region in each S/D cavity, wherein each S/D region comprises the second impurity having a second concentration greater than the first concentration.

Abstract: A semiconductor device including: a semiconductor substrate; a first gate trench portion and a dummy trench portion provided from an upper surface of the semiconductor substrate to a drift region, extending in the extending direction; a first transistor mesa portion sandwiched by the first gate trench portion and dummy trench portion; a base region contacting with the first gate trench portion above the drift region; an emitter region contacting with the same on the semiconductor substrate upper surface; and a second conductivity type region exposed on the semiconductor substrate upper surface, wherein the emitter region and second conductivity type region are arranged alternately in the extending direction; and the emitter region width in the extending direction contacting with the first gate trench portion is greater than the second conductivity type region width in the extending direction contacting with the same, will be provided.

Abstract: In one embodiment, a TVS semiconductor device includes a P-N diode that is connected in parallel with a bipolar transistor wherein a breakdown voltage of the bipolar transistor is less than a breakdown voltage of the P-N diode.

Abstract: A method for producing an organic electronic device is disclosed. In an embodiment the method includes applying an organic material to a substrate to form at least one organic functional layer, applying a patterned electrode material to the at least one organic functional layer by a first mask, and removing the organic material from regions which are free of the electrode material.

Abstract: An expanding method for expanding an expandable sheet is provided. A wafer is attached to a central portion of the expandable sheet and an annular frame is attached to a peripheral portion of the expandable sheet. The expanding method includes an annular frame holding step of holding the annular frame by using a holding unit, an expanding step of pushing the expandable sheet by using a pushing unit, thereby expanding the expandable sheet, a suction holding step of holding the wafer through the expandable sheet on a holding table under suction, and a push force removing step of removing a push force applied from the pushing unit to the expandable sheet. A minute projection for preventing the shrinkage of the expandable sheet is formed on the holding table along the outer circumference thereof.

Abstract: An embodiment is MEMS device including a first MEMS die having a first cavity at a first pressure, a second MEMS die having a second cavity at a second pressure, the second pressure being different from the first pressure, and a molding material surrounding the first MEMS die and the second MEMS die, the molding material having a first surface over the first and the second MEMS dies. The device further includes a first set of electrical connectors in the molding material, each of the first set of electrical connectors coupling at least one of the first and the second MEMS dies to the first surface of the molding material, and a second set of electrical connectors over the first surface of the molding material, each of the second set of electrical connectors being coupled to at least one of the first set of electrical connectors.

Abstract: The present invention provides a method for enhancing the efficiency of a photovoltaic module by subjecting it to extremely-low-frequency (ELF) electromagnetic radiation (EMR). The ELF EMR can be provided by a plurality of identical Jacob's ladders and the traveling arcs generated thereby. Alternatively, the ELF EMR can be provided by passing the photovoltaic module over an array of quartz discharge tubes in which arcs are generated between pairs of tungsten electrodes. The photovoltaic module is subjected to multiple passes in order to provide an optimum level of enhancement to the module.

Abstract: In an embodiment, a device includes: a substrate having a first side and a second side opposite the first side; an interconnect structure adjacent the first side of the substrate; and an integrated circuit device attached to the interconnect structure; a through via extending from the first side of the substrate to the second side of the substrate, the through via being electrically connected to the integrated circuit device; an under bump metallurgy (UBM) adjacent the second side of the substrate and contacting the through via; a conductive bump on the UBM, the conductive bump and the UBM being a continuous conductive material, the conductive bump laterally offset from the through via; and an underfill surrounding the UBM and the conductive bump.

Abstract: The present disclosure relates to the field of semiconductor technologies, and discloses semiconductor devices and manufacturing methods for the same. A semiconductor device may include: a substrate; a first active region on the substrate; a first gate structure positioned on the first active region; and a first source and a first drain that are positioned in the first active region and respectively on two sides of the first gate structure, where a size of the first drain is larger than a size of the first source. In forms of the present disclosure, because the size of the first drain is larger than the size of the first source, a current from the first drain to the first source is greater than a current from the first source to the first drain, so that the semiconductor device can make a read current relatively low and a write current relatively high in a static random access memory (SRAM), thereby improving a read margin and a write margin.

Abstract: There is provided a technique that includes forming a nitride film on a pattern including a concave portion formed in a surface of a substrate by repeating a cycle. The cycle includes non-simultaneously performing: (a) forming a first layer by supplying a precursor gas to the substrate; (b) forming an NH-terminated second layer by supplying a hydrogen nitride-based gas to the substrate to nitride the first layer; and (c) modifying a part of the NH termination to an N termination, and maintaining another part of the NH termination as it is without modifying the another part to the N termination by plasma-exciting and supplying a nitrogen gas to the substrate, wherein in (c), an N termination ratio in an upper portion of the concave portion of the pattern is made higher than an N termination ratio in a lower portion of the concave portion of the pattern.

Abstract: A method of manufacture of a non-volatile memory system comprising: forming a dielectric layer having a hole; depositing a first electrode in the hole of the dielectric layer; applying an ion source layer over the first electrode; and depositing a second electrode over the ion source layer including: depositing an interface layer on the ion source layer, and applying a cap layer on the interface layer.

Abstract: A semiconductor device production method includes performing trench etching to form a trench in a thickness direction of a semiconductor layer so that both of a first pattern portion and a second pattern portion whose side walls face each other across the trench are formed. In the trench etching, the semiconductor layer is etched and removed while a protective film is formed on a surface of the semiconductor layer, and the trench etching is performed so that the first pattern portion and the second pattern portion are configured to have a same potential or a same temperature during the trench etching.

Abstract: In a method for manufacturing a semiconductor device, a substrate is provided. A hard mask and a mask layer are formed on a first region and a second region of the substrate. The substrate is recessed using the hard mask and the mask layer to form a fin structure in the first region and a raised structure in the second region. First isolation structures and second isolation structures are formed on lower portions of opposite sidewalls of the fin structure and opposite sidewalls of the raised structure. A first gate structure is formed on a portion of the fin structure, and a second gate structure is formed on a portion of the raised structure. A first source and a first drain are formed on opposite sides of the first gate structure, and a second source and a second drain are formed on opposite sides of the second gate structure.

Abstract: Some embodiments include methods of forming memory cells. Heater structures are formed over an array of electrical nodes, and phase change material is formed across the heater structures. The phase change material is patterned into a plurality of confined structures, with the confined structures being in one-to-one correspondence with the heater structures and being spaced from one another by one or more insulative materials that entirely laterally surround each of the confined structures. Some embodiments include memory arrays having heater structures over an array of electrical nodes. Confined phase change material structures are over the heater structures and in one-to-one correspondence with the heater structures. The confined phase change material structures are spaced from one another by one or more insulative materials that entirely laterally surround each of the confined phase change material structures.

Abstract: A semiconductor structure and a fabrication method are provided. The fabrication method includes: providing a substrate; forming a dielectric layer with an opening on the substrate; forming a first barrier layer on sidewall and bottom surfaces of the opening, the first barrier layer being doped by manganese; and forming a metal interconnect on the first barrier layer, the metal interconnect being located within the opening.

Abstract: A display including a back plate, a plurality of light emitting devices and a plurality of compensating light emitting devices is provided. The back plate has a plurality of pixels and at least one compensated region. The compensated region includes some of the pixels. The light emitting devices are arranged in all the pixels on the back plate. The compensated light emitting devices are disposed on the back plate and located in each pixel in the compensated region respectively. At least one of the pixels in the compensated region is dead pixel. Besides, a repair method of the display is also provided.

Abstract: Disclosed is a flexible display apparatus. The flexible display apparatus includes a display part, a first adhesive film, an optical film, a second adhesive film, and a window film sequentially stacked, and the second adhesive film has a water-vapor permeability of about 200 g/m2·24 hr or less, and the first adhesive film has a lower restoration force than the second adhesive film, as calculated by the Equation B set forth herein.

Abstract: A method for forming a trench diode for a power semiconductor device includes forming a first trench having a first opening and a second trench having a second opening in a substrate material, the second opening of the second trench being wider than the first opening of the first trench. An insulating layer is formed over surfaces of the first and second trenches. A first semiconductor material is provided within the first and second trenches, the first semiconductor material filling the first trench at least until the first opening is entirely plugged and partially filling the second trench so that a portion of the second opening remains open, the first semiconductor material having a first conductivity type. A second semiconductor material is provided within the second trench and over the first semiconductor material, the second semiconductor material having a second conductivity type that is different from the first conductivity type.

Abstract: Single-layer CNT composites and multilayered or multitiered structures formed therefrom, by stacking of vertically aligned carbon nanotube (CNT) arrays, and methods of making and using thereof are described herein. Such multilayered or multitiered structures can be used as thermal interface materials (TIMs) for a variety of applications, such as burn-in testing.

Abstract: To provide a method for producing a Group III nitride semiconductor light-emitting device, which allows the formation of a high-temperature AlN buffer layer on an uneven substrate. This production method comprises forming an Al layer or Al droplets on the uneven shape of the uneven substrate, forming an AlN buffer layer while nitriding the Al layer; and forming a Group III nitride semiconductor layer on the AlN buffer layer. In the forming an Al layer, the internal pressure of a furnace is 1 kPa to 19 kPa, the temperature of the uneven substrate is 900° C. to 1,500° C., and an organic metal gas containing Al is supplied at a flow rate of 1.5×10?4 mol/min or more.