A semiconductor device includes a semiconductor body having opposite first and second surfaces. The semiconductor device further includes a transistor structure in the semiconductor body and a source contact structure overlapping the transistor structure. The source contact structure is electrically connected to source regions of the transistor structure. A gate contact structure is further provided, which has a part separated from the source contact structure by a longitudinal gap within a lateral plane. Gate interconnecting structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and a gate electrode of the transistor structure. Electrostatic discharge protection structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and the source contact structure. At least one of the gate interconnecting structures is between two of the electrostatic discharge protection structures along a length direction of the longitudinal gap.

Provided is a switch apparatus including a conductor; a switching device that contacts the conductor on a first surface and switches between a first terminal on the first surface side and a second terminal on a second surface side that is opposite to the first surface; and a control device that contacts the conductor on a third surface and includes a control circuit of the switching device provided on a fourth surface side opposite to the third surface and a first withstand voltage structure that protects the control circuit from excessive voltage added to the conductor. By providing the withstand voltage structure in the control device, it is possible to protect the control circuit.

An ion implantation apparatus includes an ion beam directing unit, a substrate support, and a controller. The controller is configured to effect a relative movement between an ion beam passing the ion beam directing unit and the substrate support. A beam track of the ion beam on a substrate mounted on the substrate support includes circles or a spiral.

A method of manufacturing a semiconductor device includes preparing a semiconductor layer having an element region and an outer peripheral region, forming a step portion surrounding the outer periphery of the element region in the outer peripheral region, and forming a metal layer along the step portion. The metal layer extends to cover at least a portion of a sidewall of the step portion. The method of manufacturing the semiconductor device further includes dividing the semiconductor layer into element regions on an outside of the step portion when viewed from the element region.

A semiconductor device includes a semiconductor substrate having a first region and a second region. The first region includes a first set of fin structures, the first set of fin structures comprising a first set of epitaxial anti-punch-through features of a first conductivity type. The first region further includes a first set of transistors formed over the first set of fin structures. The second region includes a second set of fin structures, the second set of fin structures comprising a second set of epitaxial anti-punch-through features of a second conductivity type opposite to the first conductivity type. The second region further includes a second set of transistors formed over the second set of fin structures. The first set of epitaxial anti-punch-through features and the second set of epitaxial anti-punch-through features are substantially co-planar.

In one embodiment, an IGBT is formed to include a region of semiconductor material. Insulated gate structures are disposed in region of semiconductor material extending from a first major surface. An n-type field stop region extends from a second major surface into the region of semiconductor material. A p+ type polycrystalline semiconductor layer is disposed adjacent to the field stop region and provides an emitter region for the IGBT. An embodiment may include a portion of the p+ type polycrystalline semiconductor being doped n-type.

A switching device includes a semiconductor substrate having a first element range including first trenches for gates, and an ineffective range not including the first trenches. In an interlayer insulating film, a contact hole is provided within the first element range, and a wide contact hole is provided within the inactive range. The first metal layer contacts the semiconductor substrate within the contact hole and the wide contact hole. The insulating protective film covers an outer peripheral side portion of a bottom surface of a second recess which is provided in a surface of the first metal layer above the wide contact hole. A side surface of an opening provided in a portion of the insulating protective film that includes the first element range is disposed in the second recess. The second metal layer contacts the first metal layer and the side surface of the opening.

A switching device including a semiconductor substrate including a trench (gate electrode) extending in a mesh shape is provided, and the upper surface of the semiconductor substrate is covered by the interlayer insulating film. Within an element range a contact hole is provided in an interlayer insulating film above each cell region while within a surrounding range an entire upper surface of each cell region is covered by the interlayer insulating film. The first metal layer covers the interlayer insulating film, and has recesses above the contact holes. The insulating protective film covers an outer peripheral side portion of the first metal layer within the surrounding range. The second metal layer covers the first metal layer within an opening of the insulating protective film. Within the surrounding range, a second conductivity-type region extending to below lower ends of the trench and is electrically connected to the body region, is provided.

A switching device includes a semiconductor substrate having a first element range and an ineffective range. First trenches extend in a first direction across the first element range and the ineffective range. Second trenches are provided in each inter-trench region within the first element range and are not provided within the ineffective range. A gate electrode is disposed in the trenches. No contact hole is provided in an interlayer insulating film within the ineffective range. The first metal layer covers the interlayer insulating film. The insulating protective film covers a portion of the first metal layer on its outer peripheral side within the ineffective range. The second metal region is in contact with the first metal layer within an opening of the insulating protective film, and is in contact with a side surface of the opening.

To provide a semiconductor device less affected by noise without making a manufacturing process more complicated and increasing a chip area. The device has a semiconductor substrate having first and second surfaces, a first-conductivity-type drain region on the second surface side in the semiconductor substrate, a first-conductivity-type drift region on the first surface side of a substrate region, a second-conductivity-type base region on the first surface side of the drift region, a first-conductivity-type source region on the first surface of the semiconductor substrate sandwiching a base region between the source and drift regions, a gate electrode opposite to and insulated from the base region, a wiring on the first main surface electrically coupled to the source region, and a first conductive film on the first main surface, opposite to and insulated from the wiring, and electrically coupled to the substrate region.