Abstract: A semiconductor battery includes a substrate, a battery anode semiconductor material arranged in or over the substrate, a battery cathode material arranged in or over the substrate and a battery electrolyte disposed between the battery anode semiconductor material and the battery cathode material. An electrically insulating encapsulant has a first face and a second face. The substrate is at least partly embedded in the encapsulant. An anode electrode is electrically connected to the battery anode semiconductor material and is disposed over the second face of the encapsulant. A cathode electrode is electrically connected to the battery cathode material and is disposed over the first face of the encapsulant.

Abstract: A method for manufacturing a semiconductor device includes providing a semiconductor substrate having a first side. A trench having a bottom is formed. The trench separates a first mesa region from a second mesa region formed in the semiconductor substrate. The trench is filled with an insulating material, and the second mesa region is removed relative to the insulating material filled in the trench to form a recess in the semiconductor substrate. In a common process, a first silicide layer is formed on and in contact with a top region of the first mesa region at the first side of the semiconductor substrate and a second silicide layer is formed on and in contact with the bottom of the recess.

Abstract: A battery includes at least two externally accessible battery electrodes to provide a supply voltage and at least more than half of a wafer including at least two wafer electrodes. The wafer includes a plurality of trenches reaching into the wafer. At least a part of a trench of the plurality of trenches is filled with a solid state battery structure. The solid state battery structure within the trench includes electrodes electrically connected to the wafer electrodes.

Abstract: A semiconductor component includes semiconductor fins formed between a base plane and a main surface of a semiconductor body. Each semiconductor fin includes a source region formed between the main surface and a channel/body region, and a drift zone formed between the channel/body region and the base plane. The semiconductor component further includes gate electrode structures on two mutually opposite sides of each channel/body region, and a field electrode structure between mutually adjacent ones of the semiconductor fins. Each field electrode structure is separated from the drift zone by a field dielectric and extends from the main surface as far as the base plane. The gate electrode structures assigned to the mutually adjacent semiconductor fins enclose an upper portion of the corresponding field electrode structure from two sides.

Abstract: A layer stack is formed on a main surface of a semiconductor layer, wherein the layer stack includes a dielectric capping layer and a metal layer between the capping layer and the semiconductor layer. Second portions of the layer stack are removed to form gaps between remnant first portions. Adjustment structures of a second dielectric material are formed in the gaps. An interlayer of the first or a third dielectric material is formed that covers the adjustment structures and the first portions. Contact trenches are formed that extend through the interlayer and the capping layer to metal structures formed from remnant portions of the metal layer in the first portions, wherein the capping layer is etched selectively against the auxiliary structures.

Abstract: A semiconductor device includes a semiconductor substrate having a first side. At least a first doping region is formed in the semiconductor substrate. The first doping region has a laterally varying doping dosage and/or a laterally varying implantation depth.

Abstract: A method includes forming a first trench in a semiconductor body between two semiconductor fins, filling the first trench with a first filling material, partially removing the first filling material by forming a second trench such that the second trench has a lower aspect ratio than the first trench, and at least partially filling the second trench with a second filling material so as to form a continuous material layer on the first filling material. A semiconductor device includes a first trench in a semiconductor body between two semiconductor fins, the first trench being filled with a first filling material, and a second trench having a lower aspect ratio than the first trench and being at least partially filled with a second filling material which forms a continuous material layer on the first filling material.

Abstract: A method for forming a semiconductor device includes providing a semiconductor substrate having an upper side and comprising, in a vertical cross-section substantially orthogonal to the upper side, a plurality of semiconductor mesas of a first monocrystalline semiconductor material which are spaced apart from each other by sacrificial layers selectively etchable with respect to the first monocrystalline semiconductor material and arranged in trenches extending from the upper side into the semiconductor substrate, forming on the semiconductor mesas a support structure mechanically connecting the semiconductor mesas, at least partly replacing the sacrificial layers while the semiconductor mesas remain mechanically connected via the support structure, and at least partly removing the support structure.

Abstract: A Transistor arrangement in a semiconductor body comprises a power transistor with at least two transistor cells, each transistor cell arranged in a semiconductor fin of the semiconductor body and with a voltage limiting device with at least two device cells. Each device cell is arranged adjacent a transistor cell in the semiconductor fin of the respective transistor cell and the voltage limiting device is separated from the power transistor by a dielectric layer.

Abstract: A method for processing a carrier may include: forming a plurality of structure elements at least one of over and in a carrier, wherein at least two adjacent structure elements of the plurality of structure elements have a first distance between each other; depositing a first layer over the plurality of structure elements having a thickness which equals the first distance between the at least two adjacent structure elements; forming at least one additional layer over the first layer, wherein the at least one additional layer covers an exposed surface of the first layer; removing a portion of the at least one additional layer to expose the first layer partially; and partially removing the first layer, wherein at least one sidewall of the at least two adjacent structure elements is partially exposed.

Abstract: A method of manufacturing a semiconductor device includes etching cavities into a semiconductor layer by crystallographic etching having an etch rate that depends upon an orientation of crystal planes, wherein a transistor fin is formed between two of the cavities at a distance to a first surface of the semiconductor layer, forming a channel/body zone of a transistor cell in the transistor fin, and forming source zones and drain regions of the transistor cell in the semiconductor layer, wherein junctions between the channel/body zone and the source zones as well as the drain regions are formed at a distance to the first surface.

Abstract: A method for producing a semiconductor device is provided. The method includes: forming in a semiconductor substrate a plurality of semiconductor mesas extending to an upper side so that adjacent semiconductor mesas are spaced apart from each other by one of a substantially empty trench and a trench substantially filled with a sacrificial layer selectively etchable with respect to the semiconductor mesas; forming a support structure mechanically connecting the semiconductor mesas spaced apart from each other by one of the substantially empty trench and the trench substantially filled with the sacrificial layer; and processing the semiconductor substrate from the upper side while the semiconductor mesas are mechanically connected via the support structure.

Abstract: A method for processing a carrier may include: forming a plurality of structure elements at least one of over and in a carrier, wherein at least two adjacent structure elements of the plurality of structure elements have a first distance between each other; depositing a first layer over the plurality of structure elements having a thickness which equals the first distance between the at least two adjacent structure elements; forming at least one additional layer over the first layer, wherein the at least one additional layer covers an exposed surface of the first layer; removing a portion of the at least one additional layer to expose the first layer partially; and partially removing the first layer, wherein at least one sidewall of the at least two adjacent structure elements is partially exposed.

Abstract: A method for forming an insulation structure in a semiconductor body includes forming a trench extending from a first surface into a semiconductor body, the trench having a first width in a horizontal direction of the semiconductor body, and forming a void spaced apart from the first surface in a vertical direction of the semiconductor body, the void having a second width in a horizontal direction that is greater than the first width, wherein the trench and the void are arranged adjacent to each other in a vertical direction.

Abstract: A semiconductor device includes a source zone of a first conductivity type formed in a first electrode fin that extends from a first surface into a semiconductor portion. A drain region of the first conductivity type is formed in a second electrode fin that extends from the first surface into the semiconductor portion. A channel/body zone is formed in a transistor fin that extends between the first and second electrode fins at a distance to the first surface. The first and second electrode fins extend along a first lateral direction. A width of first gate sections, which are arranged on opposing sides of the transistor fin, along a second lateral direction perpendicular to the first lateral direction is greater than a distance between the first and second electrode fins.

Abstract: A semiconductor device includes a buried doped region at a first distance to a main surface of a semiconductor body. A contact structure extends from the main surface to the doped region. The contact structure includes a contact layer formed from a metal-semiconductor alloy that directly adjoins the doped region. The contact structure further includes a fill structure formed from a metal or a conductive metal compound. An insulator structure surrounds the contact structure in cross-sections parallel to the main surface.

Abstract: A semiconductor component includes semiconductor fins formed between a base plane and a main surface of a semiconductor body. Each semiconductor fin includes a source region formed between the main surface and a channel/body region, and a drift zone formed between the channel/body region and the base plane. The semiconductor component further includes gate electrode structures on two mutually opposite sides of each channel/body region, and a field electrode structure between mutually adjacent ones of the semiconductor fins. Each field electrode structure is separated from the drift zone by a field dielectric and extends from the main surface as far as the base plane. The gate electrode structures assigned to the mutually adjacent semiconductor fins enclose an upper portion of the corresponding field electrode structure from two sides.

Abstract: A method for manufacturing a plurality of nanowires, the method including: providing a carrier comprising an exposed surface of a material to be processed and applying a plasma treatment on the exposed surface of the material to be processed to thereby form a plurality of nanowires from the material to be processed during the plasma treatment.

Abstract: A semiconductor device includes a first gate electrode structure, a second gate electrode structure, a device separation structure, and cell separation structures. The first gate electrode structure is buried in a semiconductor portion in a first cell array at a distance to a first surface of the semiconductor portion. The first gate electrode structure includes parallel array stripes. The second gate electrode structure is buried in the semiconductor portion in a second cell array adjacent to the first cell array. The second gate electrode structure includes parallel array stripes. The device separation structure is between the first and second cell arrays. The device separation structure has a first width. The cell separation structures have at most a second width smaller than the first width and notching, at the first surface, semiconductor fins formed from sections of the semiconductor portion between the array trenches.

Abstract: A memory circuit includes a memory element which includes a first electrode layer including lithium. The memory element further includes a second electrode layer and a solid-state electrolyte layer arranged between the first electrode layer and the second electrode layer. The memory circuit also includes a memory access circuit configured to determine a memory state of the memory element.