Abstract: Various embodiments provide a mold including a pyrolytic carbon film disposed at a surface of the mold. Various embodiments relate to using a low pressure chemical vapor deposition process (LPCVD) or using a physical vapor deposition (PVD) process in order to form a pyrolytic carbon film at a surface of a mold.

Abstract: According to various embodiments, a method may include: structuring a semiconductor region to form a structured surface of the semiconductor region; disposing a dopant in the semiconductor region; and activating the dopant at least partially by irradiating the structured surface at least partially with electromagnetic radiation having at least one discrete wavelength to heat the semiconductor region at least partially.

Abstract: According to various embodiments, a method may include: structuring a semiconductor region to form a structured surface of the semiconductor region; disposing a dopant in the semiconductor region; and activating the dopant at least partially by irradiating the structured surface at least partially with electromagnetic radiation having at least one discrete wavelength to heat the semiconductor region at least partially.

Abstract: A method of manufacturing a semiconductor device includes forming a frame trench extending from a first surface into a base substrate, forming, in the frame trench, an edge termination structure comprising a glass structure, forming a conductive layer on the semiconductor substrate and the edge termination structure, and removing a portion of the conductive layer above the edge termination structure. A remnant portion of the conductive layer forms a conductive structure that covers a portion of the edge termination structure directly adjoining a sidewall of the frame trench.

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 semiconductor device includes a semiconductor body with a first surface at a first side, a second surface opposite to the first surface and an edge surface connecting the first and second surfaces. An edge termination structure includes a glass structure and extends along the edge surface, at least from a plane coplanar with the first surface towards the second surface. A conductive structure extends parallel to the first surface and overlaps the glass structure at the first side.

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: A semiconductor body having a first surface is provided. A deep doped region of the semiconductor body is formed using masked ion implantation to implant dopant atoms into a discrete region within the semiconductor body. A structured anti-reflective coating region is formed on a portion of the first surface that is aligned with the deep doped region in a lateral direction of the semiconductor body, the lateral direction being parallel to the first surface. A laser thermal anneal of the deep doped region of the semiconductor body is performed through the anti-reflective coating region thereby activating the implanted dopant atoms in the deep doped region.

Abstract: A method for forming semiconductor devices includes placing a laminar structure having electrically insulating material arranged between a plurality of electrically conductive structures onto a surface of a semiconductor wafer comprising a plurality of semiconductor device structures. An electrically conductive structure of the plurality of electrically conductive structures is located adjacent to a semiconductor device structure of the plurality of semiconductor device structures. Each electrically conductive structure of the plurality of electrically conductive structures extends from a first surface of the laminar structure towards a second opposite surface of the laminar structure.

Abstract: An ion implantation apparatus includes an ion beam directing unit, a substrate support, and a controller. The controller is configured to effect a relative movement between an ion beam passing the ion beam directing unit and the substrate support. A beam track of the ion beam on a substrate mounted on the substrate support includes circles or a spiral.

Abstract: An ion implantation apparatus includes an ion beam directing unit, a substrate support, and a controller. The controller is configured to effect a relative movement between an ion beam passing the ion beam directing unit and the substrate support. A beam track of the ion beam on a substrate mounted on the substrate support includes circles or a spiral.

Abstract: A device includes a semiconductor material having a first main surface, an opposite surface opposite to the first main surface and a side surface extending from the first main surface to the opposite surface. The device further includes a first electrical contact element arranged on the first main surface of the semiconductor material and a glass material. The glass material includes a second main surface wherein the glass material contacts the side surface of the semiconductor material and wherein the first main surface of the semiconductor material and the second main surface of the glass material are arranged in a common plane.

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 semiconductor device includes a semiconductor body and an edge termination structure. The edge termination structure comprises a first oxide layer, a second oxide layer, a semiconductor mesa region between the first oxide layer and the second oxide layer, and a doped field region comprising a first section in the semiconductor mesa region, and a second section in a region below the semiconductor mesa region. The second section overlaps the first and the second oxide layers in the region below the semiconductor mesa region.

Abstract: A Magnetic Czochralski semiconductor wafer having opposing first and second sides arranged distant from one another in a first vertical direction is treated by implanting first particles into the semiconductor wafer via the second side to form crystal defects in the semiconductor wafer. The crystal defects have a maximum defect concentration at a first depth. The semiconductor wafer is heated in a first thermal process to form radiation induced donors. Implantation energy and dose are chosen such that the semiconductor wafer has, after the first thermal process, an n-doped semiconductor region arranged between the second side and first depth, and the n-doped semiconductor region has, in the first vertical direction, a local maximum of a net doping concentration between the first depth and second side and a local minimum of the net doping concentration between the first depth and first maximum.

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 lithium ion battery includes a first substrate having a first main surface, and a lid including an insulating material. The lid is attached to the first main surface of the first substrate, and a cavity is defined between the first substrate and the lid. The lithium ion battery further includes an electrical interconnection element in the lid, the electrical interconnection element providing an electrical connection between a first main surface and a second main surface of the lid. The lithium ion battery further includes an electrolyte in the cavity, an anode at the first substrate, the anode including a component made of a semiconductor material, and a cathode at the lid.

Abstract: A semiconductor device includes a semiconductor body with a first surface at a first side, a second surface opposite to the first surface and an edge surface connecting the first and second surfaces. An edge termination structure includes a glass structure and extends along the edge surface, at least from a plane coplanar with the first surface towards the second surface. A conductive structure extends parallel to the first surface and overlaps the glass structure at the first side.

Abstract: A battery includes a first substrate having a first main surface, a second substrate made of a conducting material or semiconductor material, and a carrier of an insulating material. The carrier has a first and a second main surfaces, the second substrate being attached to the first main surface of the carrier. An opening is formed in the second main surface of the carrier to uncover a portion of a second main surface of the second substrate. The second main surface of the carrier is attached to the first substrate, thereby forming a cavity. The battery further includes an electrolyte disposed in the cavity.

Abstract: A semiconductor device includes an IGBT having a semiconductor body including a transistor cell array in a first area. A junction termination structure is in a second area surrounding the transistor cell array at a first side of the semiconductor body. An emitter region of a first conductivity type is at a second side of the semiconductor body opposite the first side. The device further includes a diode. One of the diode anode and cathode includes the body region. The other one of the anode and the cathode includes a plurality of distinct first emitter short regions of a second conductivity type at the second side facing the transistor cell array, and at least one second emitter short region of the second conductivity type at the second side facing the junction termination structure. The at least one second emitter short region is distinct from the first emitter short regions.