A semiconductor device includes an electrically conductive lead frame which includes a die pad and a plurality of electrically conductive leads, each of the leads in the plurality being spaced apart from the die pad. The semiconductor device further includes first and second integrated switching devices mounted on the die pad, each of the first and second integrated switching devices include electrically conductive gate, source and drain terminals. The source terminal of the first integrated switching device is disposed on a rear surface of the first integrated switching device that faces and electrically connects with the die pad. The drain terminal of the second integrated switching device is disposed on a rear surface of the second integrated switching device that faces and electrically connects with the die pad.

A semiconductor device includes a semiconductor body having first and second opposite sides, a drift region, a body layer at the second side, and a field-stop region in Ohmic connection with the body layer. A source metallization at the second side is in Ohmic connection with the body layer. A drain metallization at the first side is in Ohmic connection with the drift region. A gate electrode at the second side is electrically insulated from the semiconductor body to define an operable switchable channel region in the body layer. A through contact structure extends at least between the first and second sides, and includes a conductive region in Ohmic connection with the gate electrode and a dielectric layer. In a normal projection onto a horizontal plane substantially parallel to the first side, the field-stop region surrounds at least one of the drift region and the gate electrode.

A power semiconductor device includes a semiconductor-on-insulator island having a semiconductor region and an insulation structure, the insulation structure being formed by an oxide and separating the semiconductor region from a portion of a semiconductor body of the power semiconductor device. The insulation structure includes a sidewall that laterally confines the semiconductor region; a bottom that vertically confines the semiconductor region; and a local deepening that forms at least a part of a transition between the sidewall and the bottom, wherein the local deepening extends further along the extension direction as compared to the bottom.

A semiconductor device includes a first semiconductor structure. The first semiconductor structure includes a first semiconductor material having a band-gap. The first semiconductor structure has a first surface. An insulating layer has first and second opposing surfaces. The first surface of the insulating layer is on the first surface of the first semiconductor structure. A second semiconductor structure is on the second surface of the insulating layer and includes a second semiconductor material having a band-gap that is smaller than the band-gap of the first semiconductor material. A floating electrode couples the first semiconductor structure to the second semiconductor structure.

A MOSFET includes: a semiconductor base substrate having a super junction structure; and a gate electrode formed on a first main surface side of the semiconductor base substrate by way of a gate insulation film. In a graph where a depth x at a predetermined depth position in the super junction structure is taken on an axis of abscissas, and an average positive charge density (x) at the predetermined depth position in the super junction structure is taken on an axis of ordinates, the average positive charge density (x) at a predetermined depth position of the super junction structure when the super junction structure is depleted by turning off the MOSFET is expressed by an upward convex curve projecting in a right upward direction.

A power semiconductor device includes a semiconductor-on-insulator island having a semiconductor region and an insulation structure, the insulation structure being formed by an oxide and separating the semiconductor region from a portion of a semiconductor body of the power semiconductor device. The insulation structure includes a sidewall that laterally confines the semiconductor region; a bottom that vertically confines the semiconductor region; and a local deepening that forms at least a part of a transition between the sidewall and the bottom, wherein the local deepening extends further along the extension direction as compared to the bottom.

A cost effective process flow for manufacturing semiconductor on insulator structures is parallel is provided. Each of the multiple semiconductor-on-insulator composite structures prepared in parallel comprises a charge trapping layer (CTL).

A MOSFET includes: a semiconductor base substrate having a super junction structure; and a gate electrode formed on a first main surface side of the semiconductor base substrate by way of a gate insulation film. In a graph where a depth x at a predetermined depth position in the super junction structure is taken on an axis of abscissas, and an average positive charge density (x) at the predetermined depth position in the super junction structure is taken on an axis of ordinates, the average positive charge density (x) at a predetermined depth position of the super junction structure when the super junction structure is depleted by turning off the MOSFET is expressed by an upward convex curve projecting in a right upward direction.

A method of manufacturing a semiconductor device includes forming an auxiliary mask including a plurality of mask openings on a main surface of a crystalline semiconductor substrate. A porous structure is formed in the semiconductor substrate. The porous structure includes a porous layer at a distance to the main surface and porous columns that extend from the porous layer into direction of the main surface and that are laterally separated from each other by a non-porous portion. A non-porous device layer is formed on the non-porous portion and on the porous columns.

A semiconductor device includes an electrically conductive lead frame which includes a die pad and a plurality of electrically conductive leads, each of the leads in the plurality being spaced apart from the die pad. The semiconductor device further includes first and second integrated switching devices mounted on the die pad, each of the first and second integrated switching devices include electrically conductive gate, source and drain terminals. The source terminal of the first integrated switching device is disposed on a rear surface of the first integrated switching device that faces and electrically connects with the die pad. The drain terminal of the second integrated switching device is disposed on a rear surface of the second integrated switching device that faces and electrically connects with the die pad.