Abstract: A semiconductor device includes a substrate having an active region, a gate structure disposed on the active region, a source/drain region disposed in the active region at a side of the gate structure, a first interlayer insulating layer and a second interlayer insulating layer sequentially disposed on the gate structure and the source/drain region, a first contact plug connected to the source/drain region through the first interlayer insulating layer, a second contact plug connected to the gate structure through the first interlayer insulating layer and the second interlayer insulating layer, a first metal line disposed on the second interlayer insulating layer, and having a metal via disposed in the second interlayer insulating layer and connected to the first contact plug, and a second metal line disposed on the second interlayer insulating layer, and directly connected to the second contact plug. An interval between the first contact plug and the second contact plug may be about 10 nm or less.

Abstract: Provided is a method of manufacturing a semiconductor device with improved manufacturing efficiency for the semiconductor device. The method of manufacturing a semiconductor device includes the steps of: (a) forming a circuit at a front surface side of a wafer (semiconductor wafer) having the front surface and a back surface opposite to the front surface; (b) grinding the back surface of the wafer that has a center part (first part) and a peripheral edge part (second part) surrounding a periphery of the center part in such a manner that the center part is thinner than the peripheral edge part; (c) attaching an upper surface (bonding surface) of a holding tape to the front surface of the wafer; and (d) separating the center part from the peripheral edge part by cutting a part of the center part with a blade (rotary blade) while the wafer is held by the first tape.

Abstract: A semiconductor device is provided having a first region and a second region surrounding the first region includes a first electrode, a second electrode, a first semiconductor layer of a first conductivity type between the first electrode and the second electrode, a second semiconductor layer of the first conductivity type located over the first semiconductor layer, a third semiconductor layer of the second conductivity type on the second semiconductor layer in the first region, a fourth semiconductor layer of the first conductivity type between the third semiconductor layer and the second semiconductor layer, a fifth semiconductor layer of the second conductivity type on the second semiconductor layer in the second region, and a sixth semiconductor layer of the first conductivity type located between the fifth semiconductor layer and the second semiconductor layer, wherein the width of the fourth semiconductor layer is less than the width of the sixth semiconductor layer.

Abstract: Provided herein may be a semiconductor device and a method of manufacturing the same. The method of manufacturing the semiconductor device may include forming a tunnel insulating layer in a channel hole passing through a preliminary stack structure in which interlayer insulating layers and material layers are alternately stacked. The method may include forming recess areas by removing the material layers exposed through a slit passing through the preliminary stack structure. The method may include forming a data storage layer in the recess areas through the slit. The thickness of the data storage layer may be formed regardless of a size of the channel hole.

Abstract: Structures that include an airgap and methods for forming a structure that includes an airgap. A layer stack is epitaxially grown on a substrate and includes a first semiconductor layer and a second semiconductor layer on a substrate. A plurality of openings are formed that extend through a device region of the first semiconductor layer to the second semiconductor layer. The second semiconductor layer is etched through the openings and selective to the substrate and the first semiconductor layer so as to form an airgap that is arranged in a vertical direction between the substrate and the device region. A device structure is formed in the device region of the first semiconductor layer.

Abstract: A power chip and a transistor structure thereof are provided. The transistor structure includes a semiconductor substrate, a plurality of gate structures, a plurality of first doped regions and a second doped region. The gate structures are disposed on the semiconductor substrate. The first doped regions are formed respectively in a plurality of first areas surrounded by the gate structures. The second doped region is formed in a second area among the gate structures. Each of the gate structures is arranged in an enclosed ring, and the shape of each of the gate structures is octagon.

Abstract: In a semiconductor device, a first active area, a second active area, and a third active area are formed on a substrate. A first gate electrode is formed on the first active area, a second gate electrode is formed on the second active area, and a third gate electrode is formed on the third active area. The first gate electrode has a first P-work-function metal layer, a first capping layer, a first N-work-function metal layer, a first barrier metal layer, and a first conductive layer. The second gate electrode has a second capping layer, a second N-work-function metal layer, a second barrier metal layer, and a second conductive layer. The third gate electrode has a second P-work-function metal layer, a third capping layer, a third N-work-function metal layer, and a third barrier metal layer. The third gate electrode does not have the first and second conductive layers.

Abstract: A semiconductor device includes a main transistor and a sense transistor. The main transistor is disposed in a semiconductor body and includes a plurality of sections which are individually controllable via separate gate electrodes disposed above the semiconductor body. The sense transistor is disposed in the same semiconductor body as the main transistor and has the same number of individually controllable sections as the main transistor. Each individually controllable section of the sense transistor is configured to mirror current flowing through one of the individually controllable sections of the main transistor and is connected to the same gate electrode as that individually controllable section of the main transistor. An electronic circuit that includes the semiconductor device and a current sense circuit that outputs a current sense signal representing the current mirrored by the sense transistor is also provided.

Abstract: A semiconductor device includes a fin, first to fourth gate electrodes, first and second storage devices, first and second search terminals, and first and second dummy search terminals. The fin extend in a first direction. The gate electrodes intersecting the fin. The storage devices are connected with the gate electrodes. The first search terminal is connected with the second gate electrode and is spaced from the fin by a first distance. The second search terminal is connected with the third gate electrode and is spaced from the fin by a second distance different from the first distance. The first dummy search terminal is connected with the second gate electrode and is spaced from the fin by the second distance. The second dummy search terminal is connected with the third gate electrode and is spaced from the fin by the first distance.

Abstract: A chip and a method for producing the chip with a plurality of measurement regions which are provided with electrodes for electrically detecting reactions in which, in order to reliably separate the individual measurement regions from one another, a monolayer of a fluorosilane is formed on the chip surface which has strongly hydrophobic properties. Therefore, during spotting with a liquid, the drops of liquid applied by spotting can be reliably prevented from coalescing, and thus, causing mixing of the substances in the drops of liquid which are supposed to be immobilized in the measurement regions.

Abstract: A method of forming source/drain contacts with reduced capacitance and resistance, including, forming a source/drain and a channel region on an active region of a substrate, forming a dielectric fill on the source/drain, forming a trench in the dielectric fill, forming a source/drain contact in the trench, forming an inner contact mask section on a portion of an exposed top surface of the source/drain contact, removing a portion of the source/drain contact to form a channel between a sidewall of the dielectric fill and a remaining portion of the source/drain contact, where a surface area of the remaining portion of the source/drain contact is greater than the surface area of the exposed top surface of the source/drain contact, and forming a source/drain electrode fill on the remaining portion of the source/drain contact.

Abstract: A display device includes: pixels; gate lines for connecting to the pixels; a first gate driving block for connecting to first and second gate lines that are adjacent to each other; and a second gate driving block for connecting to the first gate line and the second gate line, wherein the first gate driving block includes: a first gate signal generating portion; a first transistor connected between a first output terminal of the first gate signal generating portion and the first gate line; and a second transistor connected between the first output terminal and the second gate line, wherein the second gate driving block includes: a second gate signal generating portion; a third transistor connected between a second output terminal of the second gate signal generating portion and the first gate line; and a fourth transistor connected between the second output terminal and the second gate line.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to graphene detectors integrated with optical waveguide structures and methods of manufacture. The structure includes a plurality of non-planar fin structures composed of substrate material, and a non-planar sheet of graphene material extending entirely over each of the plurality of non-planar fin structures.

Abstract: A flexible display panel includes a display region and a non-display region. Capacitors are added to an empty region of the non-display region. The capacitors have ability to buffer a release of electrostatic charges, thereby reducing damage to inner devices and metal wiring film layers caused by the electrostatic charges and protecting the metal wiring film layers from being damaged and destroyed by the electrostatic charges during manufacturing active thin-film transistors of the flexible display panel.

Abstract: A device may include a carrier, a semiconductor chip arranged over a first surface of the carrier, and an encapsulation body comprising six side surfaces and encapsulating the semiconductor chip. A second surface of the carrier opposite to the first surface of the carrier is exposed from the encapsulation body. The device may further include electrical contact elements electrically coupled to the semiconductor chip and protruding out of the encapsulation body exclusively through two opposing side surfaces of the encapsulation body which have the smallest surface areas of all the side surfaces of the encapsulation body, and an electrically insulating layer arranged over the exposed second surface of the carrier.

Abstract: A structure of a semiconductor device is described. In one aspect of the invention, a FinFET semiconductor device includes a FinFET transistor which includes a source region and a drain region disposed in a fin on a first surface of a substrate. A gate structure is disposed over a central portion of the fin. A wiring layer of conductive material is disposed over a second surface of the substrate which is opposite to the first surface of the substrate. A set of contact studs include a first contact stud which extends completely through the height of the fin in the source region and the substrate to the wiring layer. The set of contact studs also includes a second contact stud which extends completely through the height of the fin in the drain region and the substrate to the wiring layer. In other aspects of the invention, the device is a Nanosheet device or an inverter.

Abstract: A device for direct X-ray detection (516) comprises a plurality of substantially parallel conductive channels (501) separated from one another by a quantum dot material (510), thereby forming a composite material layer (517). The parallel conductive channels (501) are electrically connected to source and drain electrodes (503 504a) which enable a flow of electrical current through the conductive channels (501). The quantum dot material (510) generates electron hole pairs upon exposure to incident electromagnetic radiation and the thus generated charge results in an electric field which causes a change in electrical current passing through at least one of the conductive channels (501). The change in electrical current is indicative of one or more of the presence and magnitude of the incident electromagnetic radiation.

Abstract: The invention relates to a method for producing a semiconductor structure, characterized in that the method comprises a step (201) of depositing a crystalline passivation layer continuously covering the entire surface of a layer based on group III nitrides, said crystalline passivation layer, which is deposited from a precursor containing silicon atoms and a flow of nitrogen atoms, consisting of silicon atoms bound to the surface of the layer based on group III nitrides and arranged in a periodical arrangement such that a diffraction image of said crystalline passivation layer obtained by grazing-incidence diffraction of electrons in the direction [1-100] comprises: two fractional order diffraction lines (0, ??) and (0, ??) between the central line (0, 0) and the integer order line (0, ?1), and two fractional order diffraction lines (0, ?) and (0, ?) between the central line (0, 0) and the integer order line (0, 1).

Abstract: A measurement system according to one aspect of the present invention includes a plurality of measurement devices configured to perform measurements at a plurality of sites in a measurement target, respectively, and a measurement management apparatus configured to acquire measured data measured by each of the measurement devices via a communication network. Times timed by the measurement devices are correlated with each other. Each of the measurement devices is configured to transmit the measured data measured based on the correlated time to measurement management apparatus. The measurement management apparatus includes a measured data acquirer configured to acquire the measured data from each of the measurement devices.

Abstract: A MEMS microphone package includes a substrate including a sound hole, a first conduction part and a second conduction part, a sidewall connected with one end thereof to the substrate and having a conducting line electrically connected to the second conduction part, a cover plate connected to an opposite end of the sidewall and defining a chamber therein and having a solder pad and a fifth contact in conduction with the solder pad and electrically connected to the conducting line, a processor chip mounted on the substrate inside the chamber and electrically connected to the first conduction part and the second conduction part, and a acoustic wave sensor mounted on the substrate inside the chamber to face toward the sound hole and electrically connected to the first conduction part using flip-chip technology.