In accordance with a method of forming a semiconductor device, an auxiliary structure is formed at a first surface of a silicon semiconductor body. A semiconductor layer is formed on the semiconductor body at the first surface. Semiconductor device elements are formed at the first surface. The semiconductor body is then removed from a second surface opposite to the first surface at least up to an edge of the auxiliary structure oriented to the second surface.

Provided is a semiconductor device manufacturing method such that miniaturization of a parallel p-n layer can be achieved, and on-state resistance can be reduced. Firstly, deposition of an n.sup.-type epitaxial layer, and formation of an n-type impurity region and p-type impurity region that form an n-type region and p-type region of a parallel p-n layer, are repeatedly carried out. Furthermore, an n.sup.-type counter region is formed in the vicinity of the p-type impurity region in the uppermost n.sup.-type epitaxial layer forming the parallel p-n layer. Next, an n.sup.-type epitaxial layer is deposited on the n.sup.-type epitaxial layer. Next, a MOS gate structure is formed in the n.sup.-type epitaxial layer. At this time, when carrying out a p-type base region diffusion process, the n-type and p-type impurity regions are caused to diffuse, thereby forming the n-type region and p-type region of the parallel p-n layer.

A semiconductor chip has a semiconductor body with a bottom side and a top side arranged distant from the bottom side in a vertical direction, an active and a non-active transistor region, a drift region formed in the semiconductor body, a contact terminal for externally contacting the semiconductor chip, and a plurality of transistor cells formed in the semiconductor body. Each of the transistor cells has a first electrode. Each of a plurality of connection lines electrically connects another one of the first electrodes to the contact terminal pad at a connecting location of the respective connection line. Each of the connection lines includes a resistance section formed of a locally increased specific resistance relative to a specific resistance of adjacent semiconductor material or metal of the respective connection line. Each of the connecting locations and each of the resistance sections is arranged in the non-active transistor region.

Performance of a semiconductor device is improved without increasing an area size of a semiconductor chip. For example, a source electrode of a power transistor and an upper electrode of a capacitor element have an overlapping portion. In other word, the upper electrode of the capacitor element is formed over the source electrode of the power transistor through a capacitor insulating film. That is, the power transistor and the capacitor element are arranged in a laminated manner in a thickness direction of the semiconductor chip. As a result, it becomes possible to add a capacitor element to be electrically coupled to the power transistor while suppressing an increase in planar size of the semiconductor chip.

A method of manufacturing a semiconductor device includes: forming field electrode structures extending in a direction vertical to a first surface in a semiconductor body; forming cell mesas from portions of the semiconductor body between the field electrode structures, including body zones forming first pn junctions with a drift zone; forming gate structures between the field electrode structures and configured to control a current flow through the body zones; and forming auxiliary diode structures with a forward voltage lower than the first pn junctions and electrically connected in parallel with the first pn junctions, wherein semiconducting portions of the auxiliary diode structures are formed in the cell mesas.

A semiconductor device includes transistor cells formed inside a semiconductor body. First and second semiconductor well regions have second conductivity type dopants and are arranged external of the transistor cells. The first semiconductor well region is arranged between two transistor cells and the second semiconductor well region is electrically connected with a load contact. A separation region has first conductivity type dopants and extends from a surface of the semiconductor body along the vertical direction and is arranged between and in contact with each of the first and second semiconductor well regions. The first semiconductor well region extends at least as deep as each of body regions of two transistor cells. A transition in a first lateral direction between the separation and first semiconductor well regions extends continuously from the surface to a point in the semiconductor body at least as deep as each body region of two transistor cells.

A semiconductor device and a method for producing thereof is provided. The semiconductor device includes a plurality of device cells, each comprising a body region, a source region, and a gate electrode adjacent to the body region and dielectrically insulated from the body region by a gate dielectric; and an electrically conductive gate layer comprising the gate electrodes or electrically connected to the gate electrodes of the plurality of device cells. The gate layer is electrically connected to a gate conductor and includes at least one of an increased resistance region and a decreased resistance region.

A method of manufacturing a semiconductor device includes forming a cavity in a first semiconductor layer formed on a semiconducting base layer, the cavity extending from a process surface of the first semiconductor layer at least down to the base layer, forming a recessed mask liner on a portion of a sidewall of the cavity distant to the process surface or a mask plug in a portion of the cavity distant to the process surface, and growing a second semiconductor layer on the process surface by epitaxy, the second semiconductor layer spanning the cavity.

A semiconductor device includes a termination trench surrounding a region in which a plurality of gate trenches is provided; a p-type lower end region being in contact with a lower end of the termination trench; a p-type outer circumference region being in contact with the termination trench from an outer circumferential side and exposed on a surface of the semiconductor device; a plurality of guard ring regions of a p-type provided on an outer circumferential side of the p-type outer circumference region and exposed on the surface; and an n-type outer circumference region separating the p-type outer circumference region from the guard ring regions and separating the guard ring regions from each another.

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.