A wide gap semiconductor device has: a drift layer using wide gap semiconductor material being a first conductivity type; a well region being a second conductivity type and provided in the drift layer; a source region provided in the well region; a gate contact region provided in the well region and electrically connected to a gate pad; and a Zener diode region provided in the well region and provided between the source region and the gate contact region.

The disclosure relates to a semiconductor die with a transistor device, which has a channel region formed in a semiconductor body, a gate region aside the channel region, for controlling a channel formation, a drift region formed in the semiconductor body, and a field electrode in a field electrode trench, which extends from a frontside of the semiconductor body vertically into the drift region, wherein an insulating layer is formed on the frontside of the semiconductor body and a frontside metallization is formed on the insulating layer, and wherein a capacitor electrode is formed in the insulating layer, which is conductively connected to at least a portion of the field electrode.

A protection device includes a first inductive element connecting first and second terminals and a second inductive element connecting third and fourth terminals. A first component includes a first avalanche diode connected in parallel with a first diode string, anodes of the first avalanche diode and a last diode in the string being connected to ground, cathodes of the first avalanche diode and a first diode in the string being connected, and a tap of the first diode string being connected to the first terminal. A second protection component includes a second avalanche diode connected in parallel with a second diode string, anodes of the second avalanche diode and a last diode in the string being connected to ground, cathodes of the second avalanche diode and a first diode in the string being connected, and a tap of the second diode string being connected to the third terminal.

A semiconductor power device having shielded gate structure in an active area and trench field plate termination surrounding the active area is disclosed. A Zener diode connected between drain metal and source metal or gate metal for functioning as a SD or GD clamp diode. Trench field plate termination surrounding active area wherein only cell array located will not cause BV degradation when SD or GD poly clamped diode integrated.

According to one embodiment, a semiconductor device includes a first electrode, a semiconductor layer, a first conductive part, a second conductive part, and a second electrode. The semiconductor layer includes a first semiconductor region, a second semiconductor region, and a third semiconductor region. The first semiconductor region is electrically connected to the first electrode. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region is provided on the second semiconductor region. The first conductive part includes a buried electrode provided in the first semiconductor region with a first insulator interposed. The second conductive part includes a gate electrode provided on the buried electrode with a second insulator interposed. The first conductive part is electrically connected to the second conductive part. An electrical resistance of the first conductive part is greater than an electrical resistance of the second conductive part.

A composite power element includes a substrate structure, an insulation layer, a dielectric layer, a MOSFET, and a Zener diode. The MOSFET is formed in a transistor formation region of the substrate structure. The Zener diode is formed in a circuit element formation region of the substrate structure, and includes a Zener diode doping structure that is formed in the substrate structure and is covered by the insulation layer. The Zener diode doping structure includes a first P-type doped region and a first N-type doped region that is formed on an inner side of the first P-type doped region. The Zener diode further includes a Zener diode metal structure that is formed on the dielectric layer and sequentially passes through the dielectric layer and the insulation layer to be electrically connected to the first P-type doped region and the first N-type doped region.

A semiconductor device includes a semiconductor body having a first surface and a second surface opposite to the first surface. A transistor structure is formed is the semiconductor body. A trench structure extends from the first surface into the semiconductor body. An electrostatic discharge protection structure is accommodated in the trench structure. The electrostatic discharge protection structure includes a first terminal region and a second terminal region. A source contact structure at the first surface is electrically connected to source regions of the transistor structure and to the first terminal region. A gate contact structure at the first surface is electrically connected to a gate electrode of the transistor structure and to the second terminal region.

A semiconductor device includes a semiconductor part; first and second electrodes respectively on back and front surfaces of the semiconductor part; a control electrode provided inside a trench of the semiconductor part; a third electrode provided inside the trench; a diode element provided at the front surface of the semiconductor part; a resistance element provided on the front surface of the semiconductor part via an insulating film, the diode element being electrically connected to the second electrode; a first interconnect electrically connecting the diode element and the resistance element, the first interconnect being electrically connected to the third electrode; and a second interconnect electrically connecting the resistance element and the semiconductor part. The resistance element is connected in series to the diode element. The diode element is provided to have a rectifying property reverse to a current direction flowing from the resistance element to the second electrode.

A transistor cell includes a gate electrode and a source region of a first conductivity type. A drain/drift region is formed in a silicon carbide body. A buried region of the second conductivity type and the drain/drift region form a pn junction. The buried region and a well region form a unipolar junction. A mean net dopant density N.sub.2 of the buried region is higher than a mean net dopant density N.sub.1 of the well region. A first clamp region of the first conductivity type extends into the well region. A first low-resistive ohmic path electrically connects the first clamp region and the gate electrode. A second clamp region of the first conductivity type extends into the well region. A second low-resistive ohmic path electrically connects the second clamp region and the source region.

A silicon carbide device includes a transistor cell with a source region and a gate electrode. The source region is formed in a silicon carbide body and has a first conductivity type. A first low-resistive ohmic path electrically connects the source region and a doped region of a second conductivity type. The doped region and a floating well of the first conductivity type form a pn junction. A first clamp region having the second conductivity type extends into the floating well. A second low-resistive ohmic path electrically connects the first clamp region and the gate electrode.