Abstract: A semiconductor device includes an active fin partially protruding from an isolation pattern on a substrate, a gate structure on the active fin, a source/drain layer on a portion of the active fin adjacent to the gate structure, a source/drain layer on a portion of the active fin adjacent to the gate structure, a metal silicide pattern on the source/drain layer, and a plug on the metal silicide pattern. The plug includes a second metal pattern, a metal nitride pattern contacting an upper surface of the metal silicide pattern and covering a bottom and a sidewall of the second metal pattern, and a first metal pattern on the metal silicide pattern, the first metal pattern covering an outer sidewall of the metal nitride pattern. A nitrogen concentration of the first metal pattern gradually decreases according to a distance from the outer sidewall of the metal nitride pattern.

Abstract: A flexible planar embedded laminated electrode can be manufactured by a method in which an octadecyl trichloro silane connected on the surface of a substrate; a source electrode, a drain electrode and a gate electrode are manufactured using photoetching; mercaptopropyl trimethoxysilane is connected at surfaces of metal electrodes of the source electrode, the drain electrode and the gate electrode; a polydimethylsiloxane is spin-coated on the respective surfaces for metal electrodes of the above electrodes; the gate electrode spin-coated with polydimethylsiloxane is removed from the substrate; oxygen plasma treatments are performed, so as to form hydroxy on the surfaces; the source electrode and the drain electrode are cut, and the gate electrode, the source electrode and the drain electrode are connected to form an integral to obtain the flexible planar embedded laminated electrode.

Abstract: Provided herein is a semiconductor device including N stacked groups (where N is a natural number greater than or equal to two) sequentially stacked over a substrate, each stacked group including interlayer insulating films and conductive patterns alternately stacked, and N concave portions each having stepped sidewalls formed in the interlayer insulating films and the conductive patterns of the stacked groups, the N concave portions each having stepped sidewalls being aligned in a first direction.

Abstract: One method for manufacturing a semiconductor device includes: forming provisional active regions that are shaped such that active regions that are adjacent in an X direction are connected to each other, forming a sacrificial film, performing etching, including the sacrificial film, so as to form a plurality of first trenches that separate the active regions, embedding element-isolating insulating films in the first trenches and then removing the sacrificial film, forming first side-wall insulating films that cover the exposed side surfaces of the element-isolating insulating films and second side-wall insulating films that cover the side surfaces of the first side-wall insulating films, embedding cap insulating films in second trenches that appear due to the formation of the second side-wall insulating films, and forming a plurality of third trenches at the positions of the second side-wall insulating films and forming word lines thereunder.

Abstract: A device according to embodiments of the invention includes a first semiconductor light emitting layer disposed between a first n-type region and a first p-type region. A second semiconductor light emitting layer disposed between a second n-type region and a second p-type region is disposed over the first semiconductor light emitting layer. A non-III-nitride material separates the first and second light emitting layers.

Abstract: A technique capable of forming a film at the bottom of a deep hole having a high aspect ratio. A method of manufacturing a semiconductor device, including: (a) loading a substrate having a hole into a transfer space via a substrate loading/unloading port; (b) moving the substrate to a processing space; (c) forming a precursor in the hole by simultaneously supplying a first process gas to the substrate in the processing space and an inert gas into the transfer space with the processing space spatially connected to the transfer space and maintaining a difference between a first inner pressure of the processing space and a first inner pressure of the transfer space within a predetermined range; and (d) forming a thin film in the hole after performing (b).

Abstract: An alternating stack of insulating layers and spacer material layers is formed over a semiconductor substrate. Memory openings are formed through the alternating stack. An optional silicon-containing epitaxial pedestal and a memory film are formed in each memory opening. After forming an opening through a bottom portion of the memory film within each memory opening, a germanium-containing semiconductor layer and a dielectric layer is formed in each memory opening. Employing the memory film and the dielectric layer as a crucible, a liquid phase epitaxy anneal is performed to convert the germanium-containing semiconductor layer into a germanium-containing epitaxial channel layer. A dielectric core and a drain region can be formed over the dielectric layer. The germanium-containing epitaxial channel layer is single crystalline, and can provide a higher charge carrier mobility than a polysilicon channel.

Abstract: There is provided a method of manufacturing a semiconductor device which includes: supplying a process gas to a process chamber in a state in which a substrate with an insulating film formed thereon is mounted on a substrate support part inside the process chamber; supplying a first power from a plasma generation part to the process chamber to generate plasma and forming a first silicon nitride layer on the insulating film; and supplying a second power from an ion control part to the process chamber in parallel with the generation of plasma, to form a second silicon nitride layer having lower stress than that of the first silicon nitride layer on the first silicon nitride layer.

Abstract: In accordance with some embodiments of the present disclosure, a packaged semiconductor device includes a first package structure, at least one outer conductive bump, a second package structure, a sealing material, and an electromagnetic interference (EMI) shielding layer. The first package structure has a first cut edge. The outer conductive bump is disposed on the first package structure and has a second cut edge. The second package structure is jointed onto the first package structure. The sealing material is disposed on the first package structure, surrounds the second package structure, and covers the outer conductive bump. The sealing material has a third cut edge. The EMI shielding layer contacts the first cut edge, the second cut edge and the third cut edge. The EMI shielding layer is electrically connected with the outer conductive bump.

Abstract: A method (200) for fabricating thin-film optoelectronic devices (100), the method comprising: providing a substrate (110), forming a back-contact layer (120); forming at least one absorber layer (130) made of an ABC chalcogenide material, adding at least one alkali metal (235), and forming at least one cavity (236, 610, 612, 613) at the surface of the absorber layer wherein forming of said at least one cavity is by dissolving away from said surface of the absorber layer at least one crystal aggregate comprising at least one alkali crystal comprising at least one alkali metal. The method (200) is advantageous for more environmentally-friendly production of photovoltaic devices (100) on flexible substrates with high photovoltaic conversion efficiency and faster production rate.

Abstract: A package integrated with a power source module may be provided. The package including a substrate having an upper surface and a lower surface, a chip on the upper surface of the substrate, a first power supply on the upper surface of the substrate, the first power supply at one side of the chip, an encapsulant encapsulating the chip and the first power supply, a second power supply on the encapsulant, the second power supply electrically connected with the substrate through a connection member, the connection member penetrating through the encapsulant may be provided.

Abstract: In an IPS-mode liquid crystal display device, the area of a terminal portion is decreased. A liquid crystal display device includes a TFT substrate and a counter substrate attached to the TFT substrate with a sealing material, and includes a display region and a terminal portion formed on the TFT substrate. A shielding transparent conductive film is formed on the outer side of the counter substrate. On the terminal portion, an earth pad formed with a transparent conductive film is formed on an organic passivation film. The shielding transparent conductive film is connected to the earth pad through a conductor. Below organic passivation film of the terminal portion, a wire is formed.

Abstract: A chip for radiation measurements, the chip comprising a first substrate comprising a first sensor and a second sensor. The chip moreover comprises a second substrate comprising a first cavity and a second cavity both with oblique walls. An internal layer is present on the inside of the second cavity. The second substrate is sealed to the first substrate with the cavities on the inside such that the first cavity is above the first sensor and the second cavity is above the second sensor.

Abstract: FinFET structures and methods of forming such structures. The FinFET structures including a substrate; at least two gates disposed on the substrate; a plurality of source/drain regions within the substrate adjacent to each of the gates; a dielectric disposed between each gate and the plurality of source/drain regions adjacent to each gate; a dielectric capping layer disposed on a first one of the at least two gates, wherein no dielectric capping layer is disposed on a second one of the at least two gates; and a local interconnect electrically connected to the second one of the at least two gates, wherein the dielectric capping layer disposed on the first one of the at least two gates prevents an electrical connection between the local interconnect and the first one of the at least two gates.

Abstract: A semiconductor device including a first gate structure is disposed on the semiconductor substrate. The first gate structure includes a gate dielectric layer, a layer, a first work function metal, a second work function metal, and a fill metal. A second gate structure is also disposed on the semiconductor substrate. The second gate structure includes the gate dielectric layer, a second work function metal, and the fill metal. In an embodiment, the second gate structure also includes an etch stop layer.

Abstract: In 3D stacked multilayer semiconductor memories including NAND and NOR flash memories, a lightly boron-doped layer is formed on top of a heavily boron-doped layer to form a select transistor, wherein the former serves as a channel of the select transistor and the latter serves as an isolation region which isolates the select transistor from a memory transistor.

Abstract: A thin film transistor array substrate having a pixel arrangement structure includes a first sub-pixel for displaying a first color and a second sub-pixel for displaying a second color alternately located in a first column, and a third sub-pixel for displaying a third color in a second column adjacent to the first column, and via holes of the first through third sub-pixels in a same row are at different positions.

Abstract: A method for forming a semiconductor device includes determining at least one electrical parameter for each semiconductor device of a plurality of semiconductor devices to be formed in a semiconductor wafer. The method further includes implanting doping ions into device areas of the semiconductor wafer used for forming the plurality of semiconductor devices with laterally varying implantation doses based on the at least one electrical parameter of the plurality of semiconductor devices.

Abstract: A mask read-only memory (M-ROM) device is provided. In an M-ROM device, a first layer having a first type doping is formed in a substrate. A plurality of buried lines is formed in the first layer of the substrate. The plurality of buried lines are arranged in parallel in a first direction and isolated from each other. An epitaxial growth process is used to form a second layer on the first layer of the substrate. A plurality of diodes is formed in the second layer. The plurality of diodes is arranged in an array. Each diode includes a first electrode having a second type doping and connecting with one of the plurality of buried lines, and a second electrode having a first type doping and located on the first electrode.

Abstract: A semiconductor device and a method of manufacturing the semiconductor device are provided. The semiconductor device includes a fin extending along a first direction over a substrate and a gate structure extending in a second direction overlying the fin. The gate structure includes a gate dielectric layer overlying the fin, a gate electrode overlying the gate dielectric layer, and a first insulating gate sidewall on a first lateral surface of the gate electrode extending along the second direction. A source/drain region is formed in the fin in a region adjacent the gate structure. A portion of the source/drain region extends under the insulating gate sidewall for a substantially constant distance along the first direction.