Abstract: Provided is a semiconductor device including an insulating plate; a first conducting portion formed on a first surface of the insulating plate; a semiconductor element mounted on the first conducting portion; and a mold material that seals the first conducting portion and the semiconductor element on the first surface side of the insulating plate. A material of the insulating plate has higher adhesion with respect to the mold material than a material of the first conducting portion, and the first conducting portion includes a gap that is filled with the mold material between the first conducting portion and the insulating plate in a portion thereof.

Abstract: A semiconductor device includes an active pattern having sidewalls defined by a device isolation pattern disposed on a substrate and an upper portion protruding from a top surface of the device isolation pattern, a liner insulating layer on the sidewalls of the active pattern, a gate structure on the active pattern, and source/drain regions at both sides of the gate structure. The liner insulating layer includes a first liner insulating layer and a second liner insulating layer having a top surface higher than a top surface of the first liner insulating layer. Each of the source/drain regions includes a first portion defined by the second liner insulating layer, and a second portion protruding upward from the second liner insulating layer and covering the top surface of the first liner insulating layer.

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: Device and method of forming a device are disclosed. The device includes a substrate with a transistor component disposed in a transistor region and a micro-electrical mechanical system (MEMS) component disposed on a membrane over a lower sensor cavity in a hybrid region. The MEMS component serves as thermoelectric-based infrared sensor, a thermopile line structure which includes an absorber layer disposed over a portion of oppositely doped first and second line segments. A back-end-of-line (BEOL) dielectric is disposed on the substrate having a plurality of inter layer dielectric (ILD) layers with metal and via levels. The ILD layers include metal lines and via contacts for interconnecting the components of the device. The metal lines in the metal levels are configured to define a BEOL or an upper sensor cavity over the lower sensor cavity, and metal lines of a first metal level of the BEOL dielectric are configured to define a geometry of the MEMS component.

Abstract: Photovoltaic devices are formed by laser drilling vias through silicon substrates and, following surface preparation of the via sidewalls, plating a continuous, electrically conductive layer on the via sidewalls to electrically connect the emitter side of the cell with the back side of the cell. The electrically conductive layer can be formed on portions of a base emitter within the vias and on the back side of the substrate. Alternatively, the electrically conductive layer can be formed on a passivation layer on the via sidewalls and back side of the cell.

Abstract: A method of forming a semiconductor device is provided. The device includes a semiconductor substrate having a main surface and a rear surface vertically spaced apart from the main surface, a first doped region, a second doped region and a third doped region. The third doped region is interposed between the first and second doped regions beneath the main surface. Field plate trenches having field plates vertically extend from the main surface to a bottom that is arranged in the first doped region. A gate trench having a gate electrode vertically extends from the main surface to the first doped region. A compensation zone vertically extends from the bottom of the gate trench deeper into the first doped region. The compensation zone is laterally aligned with the gate trench and is adjacent to the field plates along a cross-sectional plane of the device that is parallel to the main surface.

Abstract: A magnetoresistive magnetic tunnel junction (MTJ) stack includes a free magnetic region, a fixed magnetic region, and a dielectric layer positioned between the free magnetic region and the fixed magnetic region. In one aspect, the fixed magnetic region consists essentially of an unpinned, fixed synthetic anti-ferromagnetic (SAF) structure which comprises (i) a first layer of one or more ferromagnetic materials, including cobalt, (ii) a multi-layer region including a plurality of layers of ferromagnetic materials, wherein the plurality of layers of ferromagnetic materials include a layer of one or more ferromagnetic materials including cobalt, and (iii) an anti-ferromagnetic coupling layer disposed between the first layer and the multi-layer region. The free magnetic region may include a circular shape, the one or more ferromagnetic materials of the first layer may include cobalt, iron and boron, and the dielectric layer may be disposed on the first layer.

Abstract: A semiconductor device includes a first contact plug on a substrate, a first lower electrode disposed on the first contact plug and extended in a thickness direction of the substrate, a first supporter pattern on the first lower electrode and including an upper surface and a lower surface, the upper surface of the first supporter pattern being higher than a top surface of the first lower electrode, a dielectric film on the first lower electrode, the upper surface of the first supporter pattern and the lower surface of the first supporter pattern and an upper electrode disposed on the dielectric film.

Abstract: A semiconductor memory device includes a semiconductor substrate, a stacked body including a plurality of electrode films stacked on the substrate and spaced from each other in a first direction, an end portion in a second direction has a staircase shape, a conductive member adjacent to the stacked body and connected to the semiconductor substrate, a first semiconductor pillar connected to the substrate and extending through a central portion of the stacked body, a second semiconductor pillar connected to the substrate and extending through the end portion of the stacked body, a charge storage member between the first semiconductor pillar and the electrode films, an insulating member between the second semiconductor pillar and an electrode film in the end portion of the stacked body, and an insulating layer between the semiconductor substrate and the second portion of the stacked body.

Abstract: A thermal flow sensor with improved measurement accuracy is provided. The thermal flow sensor includes: an air flow rate detection element with a diaphragm having a thin-film portion in a semiconductor substrate; at least one heat generating resistor on the diaphragm; at least one temperature measuring resistor that detects temperature on each of an upstream side and a downstream side of the heat generating resistor; and a correction circuit portion that processes an output signal of the air flow rate detection element on the basis of temperature difference information of at least the two temperature measuring resistors on the upstream side and the downstream side, wherein a waveform of the output signal processed by the correction circuit portion is a waveform obtained by cutting a part of a mountain part or a valley part constituting a peak value by outputting of an arbitrary predetermined value when the peak value of the waveform exceeds the arbitrary predetermined value.

Abstract: An integrated and networked system of remote operations is provided that extends remote expert NDT methodology to a variety of manufacturing and in-service processes. The functional elements of the system comprise remote NDT applications, advanced remote NDT, remote administration, remote NDT commercial operations, and remote data analytics, which are all tied together by a remote communications hub. The communications hub has communication links with computer systems of those functional elements.

Abstract: Sacrificial memory opening fill structures are formed through an alternating stack of insulating layers and sacrificial material layers. A drain select level isolation trench extending through drain select level sacrificial material layers is formed employing a combination of a photoresist layer including a linear opening and a pair of rows of sacrificial memory opening fill structures as an etch mask. Sacrificial spacers are formed on sidewalls of the drain select level isolation trench. A drain select level isolation dielectric structure is formed in a remaining volume of the drain select level isolation trench. The sacrificial memory opening fill structures are replaced with memory stack structures. The sacrificial material layers and the sacrificial spacers are replaced with a conductive material to form electrically conductive layers and conductive connector spacers.

Abstract: Provided is a ferroelectric field effect transistor (FeFET) which has a wide memory window even if the ferroelectric film thickness is 200 nm or less, and which has excellent data retention characteristics, pulse rewriting endurance and the like. An FeFET which has a structure wherein an insulating body (11) and a gate electrode conductor (4) are sequentially laminated in this order on a semiconductor base (10) that has a source region (12) and a drain region (13). The insulating body (11) is configured by laminating a first insulating body (1) and a second insulating body (2) in this order on the base (10), and the second insulating body (2) is mainly composed of an oxide of strontium, calcium, bismuth and tantalum.

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: A semiconductor device and a method for forming the semiconductor device. The semiconductor device includes a first semiconductor region having a first conductivity type; and a second semiconductor region having a second conductivity type. The first semiconductor region is configured within the second semiconductor region and a plurality of crystal defects are formed in the second semiconductor region and at least part of the first semiconductor region is surrounded by the plurality of crystal defects. Therefore, recombination of charge carriers (electrons and holes) on a lateral direction and a longitudinal direction could be taken into account, and the switching time of the semiconductor device could be adequately decreased.

Abstract: A one time programmable (OTP) memory device, a method of manufacturing the same, and an electronic device including the same, which lower a programming voltage to enhance programming efficiency, increase reliability of peripheral input/output (I/O) elements used for a design of the OTP memory device, and simplify the design, are provided. The OTP memory device includes a transistor including one of a first gate structure including a high-k dielectric layer, a rare earth element (RE) supply layer, and a second metal layer, a second gate structure including the high-k dielectric layer, a first metal layer, and the second metal layer, and a third gate structure including the high-k dielectric layer and the second metal layer.

Abstract: A thin film transistor, a method for manufacturing the thin film transistor, an array substrate comprising the thin film transistor and an organic light emitting display panel comprising the thin film transistor are provided. The thin film transistor at least comprising an active layer made of carbon nanotube material with semiconductor properties or graphene with semiconductor properties; further comprising a first conductive layer and a second conductive layer respectively located on upper and lower sides of the active layer and in contact with the active layer, the first conductive layer and the second conductive layer formed a secondary electron emitting layer with electron multiplication function. The thin film transistor is advantageous in its simple structure and simple manufacturing process.

Abstract: A sensor package structure includes a substrate, a sensor chip disposed on the substrate, several metal wires electrically connected to the substrate and the sensor chip, a translucent layer corresponding in position to the sensor chip, and an adhesive. A top surface of the sensor chip has a sensing region and a spacing region around the sensing region. The sensor chip includes several connecting pads arranged on a first portion of the top surface between the first edge and the spacing region, and a second portion of the top surface between the second edge and the spacing region is provided without any connecting pad. The width of the first portion is greater than that of the second portion. The adhesive covers the surrounding side of the sensor chip, the first portion, and the surrounding side of the translucent layer. Part of each metal wire is embedded in the adhesive.

Abstract: A magnetoresistive random access memory (MRAM) structure includes a bottom electrode structure. A magnetic tunnel junction (MTJ) element is over the bottom electrode structure. The MTJ element includes an anti-ferromagnetic material layer. A ferromagnetic pinned layer is over the anti-ferromagnetic material layer. A tunneling layer is over the ferromagnetic pinned layer. A ferromagnetic free layer is over the tunneling layer. The ferromagnetic free layer has a first portion and a demagnetized second portion. The MRAM also includes a top electrode structure over the first portion.

Abstract: Semiconductor memory devices and methods for manufacturing the same are provided. The device may include vertical channel structures that are two-dimensionally arranged on a substrate and vertically extend from the substrate. The device may also include bit lines on the vertical channel structures, and each of the bit lines may be commonly connected to the vertical channel structures arranged in a first direction. The device may further include common source lines that extend between the vertical channel structures in a second direction intersecting the first direction and a source strapping line that is disposed at the same vertical level as the bit lines and electrically connects the common source lines to each other.