Abstract: A method for forming semiconductor devices includes attaching a glass structure to a wide band-gap semiconductor wafer having a plurality of semiconductor devices. The method further includes forming at least one pad structure electrically connected to at least one doping region of a semiconductor substrate of the wide band-gap semiconductor wafer, by forming electrically conductive material within at least one opening extending through the glass structure.

Abstract: A semiconductor device includes an insulating carrier structure comprised of an insulating inorganic material. The carrier structure has a receptacle in which a semiconductor chip is disposed. The semiconductor chip has a first side, a second side and a lateral rim. The carrier structure laterally surrounds the semiconductor chip and the lateral rim. The semiconductor device also includes a metal structure on and in contact with the second side of the semiconductor chip and embedded in the carrier structure.

Abstract: A carrier substrate having a plurality of receptacles each for receiving and carrying a semiconductor chip is provided. Semiconductor chips are arranged in the receptacles, and metal is plated in the receptacles to form a metal structure on and in contact with the semiconductor chips. The carrier substrate is cut to form separate semiconductor devices.

Abstract: A method of processing a power semiconductor device includes: providing a semiconductor body of the power semiconductor device; coupling a mask to the semiconductor body; and subjecting the semiconductor body to an ion implantation such that implantation ions traverse the mask prior to entering the semiconductor body.

Abstract: A method for use in manufacturing semiconductor devices includes providing a wafer on a support, covering a central wafer portion of the wafer, and cutting a marginal wafer portion of the wafer from the wafer. According to an embodiment of an apparatus, the apparatus includes a support configured to support a wafer, a masking device configured to cover a central wafer portion of the wafer, and a cutting device configured to cut a marginal wafer portion of the wafer from the wafer.

Abstract: In one embodiment, a method of forming a current sensor device includes forming a device region comprising a magnetic sensor within and/or over a semiconductor substrate. The device region is formed adjacent a front side of the semiconductor substrate. The back side of the semiconductor substrate is attached over an insulating substrate, where the back side is opposite the front side. Sidewalls of the semiconductor substrate are exposed by dicing the semiconductor substrate from the front side without completely dicing the insulating substrate. An isolation liner is formed over all of the exposed sidewalls of the semiconductor substrate. The isolation liner and the insulating substrate include a different material. The method further includes separating the insulating substrate to form diced chips, removing at least a portion of the isolation liner from over a top surface of the device region, and forming contacts over the top surface of the device region.

Abstract: In one embodiment, a method of forming a current sensor device includes forming a device region comprising a magnetic sensor within and/or over a semiconductor substrate. The device region is formed adjacent a front side of the semiconductor substrate. The back side of the semiconductor substrate is attached over an insulating substrate, where the back side is opposite the front side. Sidewalls of the semiconductor substrate are exposed by dicing the semiconductor substrate from the front side without completely dicing the insulating substrate. An isolation liner is formed over all of the exposed sidewalls of the semiconductor substrate. The isolation liner and the insulating substrate include a different material. The method further includes separating the insulating substrate to form diced chips, removing at least a portion of the isolation liner from over a top surface of the device region, and forming contacts over the top surface of the device region.

Abstract: A semiconductor device includes a glass piece and an active semiconductor element formed in a single-crystalline semiconductor portion. The single-crystalline semiconductor portion has a working surface, a rear side surface opposite to the working surface and an edge surface connecting the working and rear side surfaces. The glass piece has a portion extending along and in direct contact with the edge surface of the single-crystalline semiconductor portion.

Abstract: A method of thinning a substrate, the method comprising subjecting the substrate to a thinning process, determining information indicative of a surface topography of the thinned substrate, and selectively removing material from at least one surface portion of the thinned substrate based on the determined information to thereby at least partially balance out thickness variations.

Abstract: A method of manufacturing a plurality of glass members comprises bringing a first main surface of a glass substrate in contact with a first working surface of a first mold substrate, the first working surface being provided with a plurality of first protruding portions, and bringing a second main surface of the glass substrate in contact with a second working surface of a second mold substrate, the second working surface being provided with a plurality of second protruding portions. The method further comprises controlling a temperature of the glass substrate to a temperature above a glass-transition temperature to form the plurality of glass members, removing the first and the second mold substrates from the glass substrate, and separating adjacent ones of the plurality of glass members.

Abstract: Various embodiments provide a method of planarizing a semiconductor wafer, wherein the method comprises providing a semiconductor wafer comprising a surface; and forming a mask layer on the surface of the semiconductor wafer, wherein a thickness of the mask layer is smaller in thinning areas, which are to be thinned for planarizing, than in areas which are not to be thinned for planarizing.

Abstract: In one embodiment, a method of forming a current sensor device includes forming a device region comprising a magnetic sensor within and/or over a semiconductor substrate. The device region is formed adjacent a front side of the semiconductor substrate. The back side of the semiconductor substrate is attached over an insulating substrate, where the back side is opposite the front side. Sidewalls of the semiconductor substrate are exposed by dicing the semiconductor substrate from the front side without completely dicing the insulating substrate. An isolation liner is formed over all of the exposed sidewalls of the semiconductor substrate. The isolation liner and the insulating substrate include a different material. The method further includes separating the insulating substrate to form diced chips, removing at least a portion of the isolation liner from over a top surface of the device region, and forming contacts over the top surface of the device region.

Abstract: A bonded system includes a reconstituted wafer including a hygroscopic material. A moisture barrier layer is arranged over a surface of the reconstituted wafer. An adhesive layer is arranged over a surface of the moisture barrier opposite the reconstituted wafer. A carrier is arranged over a surface of the adhesive layer opposite the moisture barrier. The adhesive layer adhesively bonds the reconstituted wafer and the carrier together.

Abstract: An implantable vessel fluid sensor is configured to sense at least one vessel fluid parameter of a vessel. The implantable vessel fluid sensor includes a tubular body having a first end portion. The first end portion is configured to be inserted into and to form a sealed junction with an open vessel end of the vessel. The implantable vessel fluid sensor further includes a sensor unit connected to the tubular body. The sensor unit includes a sensor region configured to be in direct contact with the vessel fluid in a sealed junction state. A minimum distance between the sensor region and the first end portion is at most 10 times an outer diameter of the first end portion of the tubular body.

Abstract: In one embodiment, a semiconductor device includes a glass substrate, a semiconductor substrate disposed on the glass substrate, and a magnetic sensor disposed within and/or over the semiconductor substrate.

Abstract: A semiconductor device includes a glass piece and an active semiconductor element formed in a single-crystalline semiconductor portion. The single-crystalline semiconductor portion has a working surface, a rear side surface opposite to the working surface and an edge surface connecting the working and rear side surfaces. The glass piece has a portion extending along and in direct contact with the edge surface of the single-crystalline semiconductor portion.

Abstract: A method for manufacturing a transformer device includes providing a glass substrate having a first side and a second side arranged opposite the first side, forming a first recess in the glass substrate at the first side of the glass substrate, forming a second recess in the glass substrate at the second side of the glass substrate opposite to the first recess, forming a first coil in the first recess, and forming a second coil in the second recess.

Abstract: A cavity is formed in a working surface of a substrate in which a semiconductor element is formed. A glass piece formed from a glass material is bonded to the substrate, and the cavity is filled with the glass material. For example, a pre-patterned glass piece is used which includes a protrusion fitting into the cavity. Cavities with widths of more than 10 micrometers are filled fast and reliably. The cavities may have inclined sidewalls.

Abstract: A carrier substrate having a plurality of receptacles each for receiving and carrying a semiconductor chip is provided. Semiconductor chips are arranged in the receptacles, and metal is plated in the receptacles to form a metal structure on and in contact with the semiconductor chips. The carrier substrate is cut to form separate semiconductor devices.

Abstract: A method for manufacturing semiconductor devices includes providing a stack having a semiconductor wafer and a glass substrate with openings and at least one trench attached to the semiconductor wafer. The semiconductor wafer includes a plurality of semiconductor devices. The openings of the glass substrate leave respective areas of the semiconductor devices uncovered by the glass substrate and the trench connects the openings. A metal layer is formed at least on exposed walls of the trench and the openings and on the uncovered areas of the semiconductor devices of the semiconductor wafer. A metal region is formed by electroplating metal in the openings and the trench and by subsequently grinding the glass substrate to remove the trenches. The stack of the semiconductor wafer and the attached glass substrate is cut to separate the semiconductor devices.