A method for forming a semiconductor device includes forming an electrical structure at a main surface of a semiconductor substrate and carrying out an anodic oxidation of a back side surface region of a back side surface of the semiconductor substrate to form an oxide layer at the back side surface of the semiconductor substrate. Additionally, the method includes connecting a carrier substrate to the oxide layer and processing a back side of the semiconductor substrate.

According to various embodiments, a semiconductor device may include: a layer stack formed at a surface of the semiconductor device, the layer stack including: a metallization layer including a first metal or metal alloy; a protection layer covering the metallization layer, the protection layer including a second metal or metal alloy, wherein the second metal or metal alloy is less noble than the first metal or metal alloy.

To provide a semiconductor device in which an edge termination structure can be made smaller easily. A semiconductor device is provided, the semiconductor device including an active region and an edge termination structure formed on a front surface side of a semiconductor substrate, wherein an edge termination structure has a guard ring provided surrounding an active region on a front surface side of a semiconductor substrate, a first field plate provided on a front surface side of a guard ring, an electrode unit provided on a front surface side of a first field plate, a second field plate provided between a first field plate and a electrode unit, and a conductive connecting unit which mutually electrically connects a first field plate, an electrode unit, a second field plate, and a guard ring.

A semiconductor device includes a drift region of a device structure arranged in a semiconductor layer. The drift region includes at least one first drift region portion and at least one second drift region portion. A majority of dopants within the first drift region portion are a first species of dopants having a diffusivity less than a diffusivity of phosphor within the semiconductor layer. Further, a majority of &pants within the second drift region portion are a second species of dopants. Additionally, the semiconductor device includes a trench extending from a surface of the semiconductor layer into the semiconductor layer. A vertical distance of a border between the first drift region portion and the second drift region portion to the surface of the semiconductor layer is larger than 0.5 times a maximal depth of the trench and less than 1.5 times the maximal depth of the trench.

A method for forming a semiconductor device includes etching, in a masked etching process, through a layer stack located on a surface of a semiconductor substrate to expose the semiconductor substrate at unmasked regions of the layer stack. The method further includes etching, in a selective etching process, at least a first layer of the layer stack located adjacently to the semiconductor substrate. A second layer of the layer stack is less etched or non-etched compared to the selective etching of the first layer of the layer stack, such that the first layer of the layer stack is laterally etched back between the semiconductor substrate and the second layer of the layer stack. The method further includes growing semiconductor material on regions of the surface of the semiconductor substrate exposed after the selective etching process.

Various improvements in vertical transistors, such as IGBTs, are disclosed. The improvements include forming periodic highly-doped p-type emitter dots in the top surface region of a growth substrate, followed by growing the various transistor layers, followed by grounding down the bottom surface of the substrate, followed by a wet etch of the bottom surface to expose the heavily doped p+ layer. A metal contact is then formed over the p+ layer. In another improvement, edge termination structures utilize p-dopants implanted in trenches to create deep p-regions for shaping the electric field, and shallow p-regions between the trenches for rapidly removing holes after turn-off. In another improvement, a dual buffer layer using an n-layer and distributed n+ regions improves breakdown voltage and saturation voltage. In another improvement, p-zones of different concentrations in a termination structure are formed by varying pitches of trenches. In another improvement, beveled saw streets increase breakdown voltage.

A semiconductor device includes transistor cells and control structures. The transistor cells include source zones of a first conductivity type and body zones of a second conductivity type. The source and body zones are formed in a semiconductor mesa formed from a portion of a semiconductor body. The control structures include first portions extending from a first surface into the semiconductor body on at least two opposing sides of the semiconductor mesa, second portions between the first portions and separated from the first surface by portions of the semiconductor mesa, and third portions connecting the first and the second portions and separated from the first surface by portions of the semiconductor mesa. Constricted sections of the semiconductor mesa separate third portions neighboring each other along a horizontal longitudinal extension of the semiconductor mesa.

A super junction semiconductor device includes a semiconductor portion having strip structures in a cell area. Each strip structure has a compensation structure with first and second sections inversely provided on opposite sides of a fill structure. Each section has first and second compensation layers of complementary conductivity types. The strip structures are linear stripes extending through the cell area in a first lateral direction and into an edge area surrounding the cell area in lateral directions. Each strip structure has an end section with a termination portion in the edge area in which the first compensation layer of the first section is connected with the first compensation layer of the second section via a first conductivity layer, and the second compensation layer of the first section is connected with the second compensation layer of the second section via a second conductivity layer.

A semiconductor device includes a semiconductor chip formed with an SiC-IGBT including an SiC semiconductor layer, a first conductive-type collector region formed such that the collector region is exposed on a second surface of the SiC semiconductor layer, a second conductive-type base region formed such that the base region contacts the collector region, a first conductive-type channel region formed such that the channel region contacts the base region, a second conductive-type emitter region formed such that the emitter region contacts the channel region to define a portion of a first surface of the SiC semiconductor layer, a collector electrode connected to the collector region, and an emitter electrode connected to the emitter region. A MOSFET of the device is connected in parallel to the SiC-IGBT, and includes a second conductive-type source region electrically connected to the emitter electrode and a second conductive-type drain region electrically connected to the collector electrode.

A vertical drift metal-oxide-semiconductor (VDMOS) transistor with improved contact to source and body regions, and a method of fabricating the same. A masked ion implant of the source regions into opposite-type body regions defines the locations of body contact regions, which are implanted subsequently with a blanket implant. The surface of the source regions and body contact regions are silicide clad, and an overlying insulator layer deposited and planarized. Contact openings are formed through the planarized insulator layer, within which conductive plugs are formed to contact the metal silicide, and thus the source and body regions of the device. A metal conductor is formed overall to the desired thickness, and contacts the conductive plugs to provide bias to the source and body regions.