A semiconductor device includes a semiconductor substrate, a transistor section, a diode section, and a boundary section provided between the transistor section and the diode section in the semiconductor substrate. The transistor section has gate trench portions which are provided from an upper surface of the semiconductor substrate to a position deeper than that of an emitter region, and to each of which a gate potential is applied. An upper-surface-side lifetime reduction region is provided on the upper surface side of the semiconductor substrate in the diode section and a partial region of the boundary section, and is not provided in a region that is overlapped with the gate trench portion in the transistor section in a surface parallel to the upper surface of the semiconductor substrate.

A semiconductor device includes a semiconductor substrate, a transistor section, a diode section, and a boundary section provided between the transistor section and the diode section in the semiconductor substrate. The transistor section has gate trench portions which are provided from an upper surface of the semiconductor substrate to a position deeper than that of an emitter region, and to each of which a gate potential is applied. An upper-surface-side lifetime reduction region is provided on the upper surface side of the semiconductor substrate in the diode section and a partial region of the boundary section, and is not provided in a region that is overlapped with the gate trench portion in the transistor section in a surface parallel to the upper surface of the semiconductor substrate.

A semiconductor device is provided that is useful for ESD protection purposes. The device includes a semiconductor die; diode unit cells integrated on the die and being electrically connected between the first and second terminal, each unit cell includes a first region of a first charge type in the die and a second region of a second charge type in the die; an isolation structure arranged in the die, the isolation structure being configured to electrically isolate the unit cells from one another in the semiconductor die; and contacts including first contacts that are electrically connected to the first terminal and second contacts that are electrically connected to the second terminal, and each contact among the first and second contacts is electrically connected to the first region of a respective unit cell among the unit cells and to the second region of another unit cell among the unit cells.

A semiconductor device is provided that is useful for ESD protection purposes. The device includes a semiconductor die; diode unit cells integrated on the die and being electrically connected between the first and second terminal, each unit cell includes a first region of a first charge type in the die and a second region of a second charge type in the die; an isolation structure arranged in the die, the isolation structure being configured to electrically isolate the unit cells from one another in the semiconductor die; and contacts including first contacts that are electrically connected to the first terminal and second contacts that are electrically connected to the second terminal, and each contact among the first and second contacts is electrically connected to the first region of a respective unit cell among the unit cells and to the second region of another unit cell among the unit cells.

The present invention introduces a new shielded gate trench SBR (Super Barrier Rectifier) wherein an epitaxial layer having special MSE (multiple stepped epitaxial) layers with different doping concentrations decreasing in a direction from a substrate to a top surface of the epitaxial layer, wherein each of the MSE layers has an uniform doping concentration as grown. Forward voltage V.sub.f is significantly reduced with the special MSE layers. An integrated circuit comprising a SGT MOSFET and a SBR formed on a single chip obtains benefits of low on-resistance, low reverse recovery time and high avalanche capability from the special MSE layers.

A method of processing a power diode includes: creating an anode region and a drift region in a semiconductor body; and forming, by a single ion implantation processing step, each of an anode contact zone and an anode damage zone in the anode region. Power diodes manufactured by the method are also described.

A method of processing a power diode includes: creating an anode region and a drift region in a semiconductor body; and forming, by a single ion implantation processing step, each of an anode contact zone and an anode damage zone in the anode region. Power diodes manufactured by the method are also described.

In a semiconductor device according to the technology disclosed in the present specification, a temperature detection region is provided with a diffusion layer of a second conductivity type provided on a surface layer of a drift layer of a first conductivity type, a well layer of a first conductivity type provided on a surface layer of the diffusion layer and electrically connected to an anode electrode, and a cathode layer of a first conductivity type provided on a surface layer of the well layer and electrically connected to a cathode electrode.

A semiconductor device includes a first switching element; a second switching element; a first metal member; a second metal member; a first terminal that has a potential on a high potential side; a second terminal that has a potential on a low potential side; a third terminal that has a midpoint potential; and a resin part. A first potential part has potential equal to potential of the first terminal. A second potential part has potential equal to potential of the second terminal. A third potential part has potential equal to potential of the third terminal. A first creepage distance between the first potential part and the second potential part is longer than a minimum value of a second creepage distance between the first potential part and the third potential part and a third creepage distance between the second potential part and the third potential part.

A semiconductor device includes a first switching element; a second switching element; a first metal member; a second metal member; a first terminal that has a potential on a high potential side; a second terminal that has a potential on a low potential side; a third terminal that has a midpoint potential; and a resin part. A first potential part has potential equal to potential of the first terminal. A second potential part has potential equal to potential of the second terminal. A third potential part has potential equal to potential of the third terminal. A first creepage distance between the first potential part and the second potential part is longer than a minimum value of a second creepage distance between the first potential part and the third potential part and a third creepage distance between the second potential part and the third potential part.