A high voltage edge termination structure for a power semiconductor device is provided. The high voltage edge termination structure comprises a semiconductor body of a first conductive type, a JTE region of a second conductive type, a heavily doped channel stop region of the first conductive type, and a plurality of field plates. The JTE region is formed in the semiconductor body, wherein the JTE region is adjacent to an active region of the power semiconductor device. The heavily doped channel stop region is formed in the semiconductor body, wherein the heavily doped channel stop region is spaced apart from the JTE region. The plurality of field plates is formed on the JTE region.

A modular concept for Silicon Carbide power devices is disclosed where a low voltage module (LVM) is designed separately from a high voltage module (HVM). The LVM having a repeating structure in at least a first direction, the repeating structure repeats with a regular distance in at least the first direction, the HVM comprising a buried grid (4) with a repeating structure in at least a second direction, the repeating structure repeats with a regular distance in at least the second direction, along any possible defined direction. Advantages include faster easier design and manufacture at a lower cost.

A semiconductor component includes: a SiC semiconductor body; a trench extending from a first surface of the SiC semiconductor body into the SiC semiconductor body, the trench having a conductive connection structure, a structure width at a bottom of the trench, and a dielectric layer covering sidewalls of the trench; a shielding region along the bottom and having a central section which has a lateral first width; and a contact formed between the conductive connection structure and the shielding region. The conductive connection structure is electrically connected to a source electrode. In at least one doping plane extending approximately parallel to the bottom, a dopant concentration in the central section deviates by not more than 10% from a maximum value of the dopant concentration in the shielding region in the doping plane. The first width is less than the structure width and is at least 30% of the structure width.

A semiconductor device includes: a semiconductor body having a first surface, a second surface opposite to the first surface in a vertical direction, an active region, and a sensor region arranged adjacent to the active region in a horizontal direction; transistor cells at least partly integrated in the active region, each transistor cell including a drift region separated from a source region by a body region, and a gate electrode dielectrically insulated from the body region; at least one sensor cell at least partly integrated in the sensor region, each sensor cell including a drift region separated from a source region by a body region, and a gate electrode dielectrically insulated from the body region; and an intermediate region arranged between the active region and the sensor region, the intermediate region including a drift region and an undoped semiconductor region extending from the first surface into the drift region.

A power semiconductor device may include a junction termination region, bounded by a side edge of a semiconductor substrate. The junction termination region may include a substrate layer of a first dopant type, a well layer of a second dopant type, a conductive trench assembly having a first set of conductive trenches, in the junction termination region, and extending from above the substrate layer through the well layer; and a metal layer, electrically connecting the conductive trench assembly to the well layer. The metal layer may include a set of inner metal contacts, electrically connecting a set of inner regions of the well layer to a first set of trenches of the conductive trench assembly; and an outer metal contact, electrically connecting an outer region of the well layer to a second set of conductive trenches of the conductive trench assembly, wherein the outer region borders the side edge.

A power semiconductor device includes: a drift region; a plurality of IGBT cells each having a plurality of trenches extending into the drift region along a vertical direction and laterally confining at least one active mesa which includes an upper section of the drift region; and an electrically floating barrier region of an opposite conductivity type as the drift region and spatially confined, in and against the vertical direction, by the drift region. A total volume of all active mesas is divided into first and second shares, the first share not laterally overlapping with the barrier region and the second share laterally overlapping with the barrier region. The first share carries the load current at least within a range of 0% to 100% of a nominal load current. The second share carries the load current if the load current exceeds at least 0.5% of the nominal load current.

The present techniques relate to a semiconductor device having resistance which has a positive temperature coefficient and a suitable value, and to a method for manufacturing a semiconductor device having resistance which has a positive temperature coefficient and a suitable value. The semiconductor device related to the present techniques is a bipolar device in which a current flows through a pn junction. The semiconductor device includes an n-type silicon carbide drift layer, a p-type first silicon carbide layer formed on the silicon carbide drift layer, and a p-type second silicon carbide layer formed on the first silicon carbide layer. Then, the second silicon carbide layer has a positive temperature coefficient of resistance.

Transistor structure including deep source and/or drain semiconductor that is contacted by metallization from both a front (e.g., top) side and a back (e.g., bottom) side of transistor structure. The deep source and/or drain semiconductor may be epitaxial, following crystallinity of a channel region that may be monocrystalline A first layer of the source and/or drain semiconductor may have lower impurity doping while a second layer of the source and/or drain semiconductor may have higher impurity doping. The deep source and/or drain semiconductor may extend below the channel region and be adjacent to a sidewall of a sub-channel region such that metallization in contact with the back side of the transistor structure may pass through a thickness of the first layer of the source and/or drain semiconductor to contact the second layer of the source and/or drain semiconductor.

A SiC semiconductor device includes a SiC chip having a main surface, a trench gate structure formed at the main surface, a trench source structure formed at the main surface away from the trench gate structure in one direction, an insulating film covering the trench gate structure and the trench source structure above the main surface, a gate main surface electrode formed on the insulating film and a gate wiring that is led out from the gate main surface electrode onto the insulating film such as to cross the trench gate structure and the trench source structure in the one direction, and that is electrically connected to the trench gate structure through the insulating film, and that faces the trench source structure with the insulating film between the trench source structure and the gate wiring.

A semiconductor device includes a vertical semiconductor element having a deep layer, a current dispersion layer, a base region, a high-concentration region, and a trench gate structure. The deep layer has multiple sections being apart to each other in one direction. The current dispersion layer is between adjacent two of the sections of the deep layer. The high-concentration region is on a portion of the base region. The trench gate structure includes a gate trench, a gate insulation film and a gate electrode. The current dispersion layer is at a bottom of the trench gate structure, and has an ion-implanted layer extending from a bottom portion of the gate trench to a bottom portion of the deep layer or a location below the bottom portion of the deep layer.