Abstract: A method for manufacturing a semiconductor substrate includes providing a first wafer having a first surface and a second surface opposite the first surface, forming cavities in the first wafer at a first distance from the first surface, wherein the cavities, when seen in a cross-section perpendicular to the first surface, are laterally spaced from each other by partition walls formed by the semiconductor material of the first wafer, the cavities forming a separation region, bonding a second wafer on the first surface of the first wafer, breaking the partition walls by applying mechanical impact to the partition walls to split the first wafer along the separation region so that a residual wafer remains attached to the second wafer, and depositing an epitaxial layer on the residual wafer.

Abstract: A method of manufacturing a semiconductor substrate includes providing a semiconductor wafer having a first surface and a second surface opposite the first surface, and forming, when seen in a cross-section perpendicular to the first surface, cavities in the semiconductor wafer at a first distance from the first surface. The cavities are laterally spaced from each other by partition walls formed by semiconductor material of the wafer. The cavities form a separation region. The method further includes forming a semiconductor layer on the first surface of the semiconductor wafer, and breaking at least some of the partition walls by applying mechanical impact to the partition walls to split the semiconductor wafer along the separation region.

Abstract: In order to produce a cost-effective fuse in chip design, which is applied to a carrier substrate made of a Al2O3 ceramic having a high thermal conductivity, and which is provided with a fusible metallic conductor and a cover layer, in which the melting point of the metallic conductor may be defined reliably, it is suggested that an intermediate layer having low thermal conductivity be positioned between the carrier substrate and the metallic conductor, the intermediate layer being formed by a low-melting-point inorganic glass paste applied in the screen-printing method or an organic intermediate layer applied in island printing. Furthermore, a method for manufacturing the fuse is specified.

Abstract: A transistor includes a source, a drain spaced apart from the source, and a heterostructure body having a two-dimensional charge carrier gas channel for connecting the source and the drain. The transistor further includes a semiconductor field plate disposed between the source and the drain. The semiconductor field plate is configured to at least partly counterbalance charges in the drain when the transistor is in an off state in which the channel is interrupted and a blocking voltage is applied to the drain. The counterbalance charge provided by the semiconductor field plate is evenly distributed over a plane or volume of the semiconductor field plate. Various semiconductor field plate configurations and corresponding manufacturing methods are described herein.

Abstract: A normally-off JFET is provided. The normally-off JFET includes a channel region of a first conductivity type, a floating semiconductor region of a second conductivity type adjoining the channel region, and a contact region of the first conductivity type adjoining the floating semiconductor region. The floating semiconductor region is arranged between the contact region and the channel region. Further, a normally-off semiconductor switch is provided.

Abstract: The present invention relates to an absorbent article comprising a plurality of first colored areas and a second colored area which are viewable by a user from a body-facing side of a topsheet, wherein the second colored area surrounds at least some of the first colored areas, a delta E between the first colored areas and the second colored area is at least about 4.5, an average mean area of the first colored areas is not smaller than about 0.20 mm2, and a density of the first colored areas is about 4-24 areas/cm2.

Abstract: A method for producing a MEMS device comprises forming a semiconductor layer stack, the semiconductor layer stack comprising at least a first monocrystalline semiconductor layer, a second monocrystalline semiconductor layer and a third monocrystalline semiconductor layer, the second monocrystalline semiconductor layer formed between the first and third monocrystalline semiconductor layers. A semiconductor material of the second monocrystalline semiconductor layer is different from semiconductor materials of the first and third monocrystalline semiconductor layers. After forming the semiconductor layer stack, at least a portion of each of the first and third monocrystalline semiconductor layers is concurrently etched.

Abstract: A MEMS device includes a fixed electrode and a movable electrode arranged isolated and spaced from the fixed electrode by a distance. The movable electrode is suspended against the fixed electrode by one or more spacers including an insulating material, wherein the movable electrode is laterally affixed to the one or more spacers.

Abstract: A method for forming a field-effect semiconductor device includes: providing a wafer having a main surface and a first semiconductor layer of a first conductivity type; forming at least two trenches from the main surface partly into the first semiconductor layer so that each of the at least two trenches includes, in a vertical cross-section substantially orthogonal to the main surface, a side wall and a bottom wall, and that a semiconductor mesa is formed between the side walls of the at least two trenches; forming at least two second semiconductor regions of a second conductivity type in the first semiconductor layer so that the bottom wall of each of the at least two trenches adjoins one of the at least two second semiconductor regions; and forming a rectifying junction at the side wall of at least one of the at least two trenches.

Abstract: A MEMS device includes a fixed electrode and a movable electrode arranged isolated and spaced from the fixed electrode by a distance. The movable electrode is suspended against the fixed electrode by one or more spacers including an insulating material, wherein the movable electrode is laterally affixed to the one or more spacers.

Abstract: A field-effect semiconductor device having a semiconductor body with a main surface is provided. The semiconductor body includes, in a vertical cross-section substantially orthogonal to the main surface, a drift layer of a first conductivity type, a semiconductor mesa of the first conductivity type adjoining the drift layer, substantially extending to the main surface and having two side walls, and two second semiconductor regions of a second conductivity type arranged next to the semiconductor mesa. Each of the two second semiconductor regions forms a pn-junction at least with the drift layer. A rectifying junction is formed at least at one of the two side walls of the mesa. Further, a method for producing a heterojunction semiconductor device is provided.

Abstract: According to an embodiment of a semiconductor device, the semiconductor device includes a semiconductor body having a main surface, the semiconductor body including a drift region of a first band-gap material, the drift region being of a first conductivity type, and a metallization arranged at the main surface. In a cross-section which is substantially orthogonal to the main surface, the semiconductor body further includes a contact region of the first band-gap material directly adjoining the drift region and the metallization, and an anode region of a second band-gap material having a lower band-gap than the first band-gap material. The contact region is of a second conductivity type. The anode region is in ohmic contact with the metallization and forms a heterojunction with the drift region.

Abstract: A sensor device is provided for detecting thawing on surfaces with interdigital electrodes formed in a resistance layer which is formed on a substrate. In order to develop the sensor device further so that the measuring speed of the sensor device is further increased, the disclosure proposes that the interdigital electrodes and recesses between the interdigital electrodes have a moisture-sensitive hydrophilic surface through condensation cores applied to it.

Abstract: According to an embodiment of a field-effect semiconductor device, the field-effect semiconductor device includes a semiconductor body and a source electrode. The semiconductor body includes a drift region, a gate region and a source region of a first semiconductor material having a first band-gap and an anode region of a second semiconductor material having a second band-gap lower than the first band-gap. The drift region is of a first conductivity type. The gate region forms a pn-junction with the drift region. The source region is of the first conductivity type and in resistive electric connection with the drift region and has a higher maximum doping concentration than the drift region. The anode region is of the second conductivity type, forms a heterojunction with the drift region and is spaced apart from the source region. The source metallization is in resistive electric connection with the source region and the anode region.

Abstract: A MEMS device includes a fixed electrode and a movable electrode arranged isolated and spaced from the fixed electrode by a distance. The movable electrode is suspended against the fixed electrode by one or more spacers including an insulating material, wherein the movable electrode is laterally affixed to the one or more spacers.

Abstract: The present invention relates to an absorbent article having a body-facing surface and a transverse centerline, comprising; a hydrophilic topsheet, a backsheet joined to the topsheet, and an absorbent core disposed between the topsheet and the backsheet, and a lateral topsheet on each longitudinal side of the body-facing surface of the absorbent article so that at least a part thereof covers the topsheet where the topsheet covers the absorbent core, wherein the lateral topsheet comprises an embedded zone along the longitudinal direction of the absorbent article comprising a plurality of compressed areas where the lateral topsheet and the topsheet are jointly compressed so that the lateral topsheet is embedded into the topsheet, and wherein the lateral topsheet in the compressed areas is one layer.

Abstract: A semiconductor device according to an embodiment is at least partially arranged in or on a substrate and includes a recess forming a mesa, wherein the mesa extends along a direction into the substrate to a bottom plane of the recess and includes a semiconducting material of a first conductivity type, the semiconducting material of the mesa including at least locally a first doping concentration not extending further into the substrate than the bottom plane. The semiconductor device further includes an electrically conductive structure arranged at least partially along a sidewall of the mesa, the electrically conductive structure forming a Schottky or Schottky-like electrical contact with the semiconducting material of the mesa, wherein the substrate comprises the semiconducting material of the first conductivity type comprising at least locally a second doping concentration different from the first doping concentration along a projection of the mesa into the substrate.

Abstract: A welding stud including a head and a shank extending from the head. The shank has an end region opposite the head and the end region includes at least two angled surfaces which incline towards an axis of the shank in a direction moving away from the head.

Abstract: A semiconductor device according to an embodiment is at least partially arranged in or on a substrate and includes a recess forming a mesa, wherein the mesa extends along a direction into the substrate to a bottom plane of the recess and includes a semiconducting material of a first conductivity type, the semiconducting material of the mesa including at least locally a first doping concentration not extending further into the substrate than the bottom plane. The semiconductor device further includes an electrically conductive structure arranged at least partially along a sidewall of the mesa, the electrically conductive structure forming a Schottky or Schottky-like electrical contact with the semiconducting material of the mesa, wherein the substrate comprises the semiconducting material of the first conductivity type comprising at least locally a second doping concentration different from the first doping concentration along a projection of the mesa into the substrate.