A semiconductor apparatus includes a plurality of semiconductor devices with a single substrate, a plurality of trench regions, each trench region including a trench, wherein the single substrate includes a substrate layer, a first epitaxial layer of a first conductivity type, disposed on the substrate layer, and a second epitaxial layer of a second conductivity type, disposed on the first epitaxial layer, wherein each trench of the plurality of trench regions extends through the second epitaxial layer and into the first epitaxial layer, thereby isolating adjacent semiconductor devices of the plurality of semiconductor devices.

A semiconductor device includes a semiconductor part, first and second electrodes, and a control electrode. The semiconductor part is provided between the first and second electrodes. The control electrode is provided in a trench of the semiconductor part between the semiconductor part and the second electrode. The semiconductor part includes first to third layers. The first layer of a first conductivity type extends between the first and second electrodes. The second layer of a second conductivity type is provided between the first layer and the second electrode. The second layer is connected to the second electrode. The third layer of the second conductivity type is provided between the second layer and the control electrode. The third layer includes a second-conductivity-type impurity with a higher concentration than a second-conductivity-type impurity of the second layer. The third layer contacts the second electrode, and is electrically connected to the second electrode.

A semiconductor device includes a collector layer, a base layer, and an emitter layer that are disposed above a substrate. An emitter mesa layer is disposed on a partial region of the emitter layer. In a plan view, the base electrode is disposed in or on a region which does not overlap the emitter mesa layer. The base electrode allows base current to flow to the base layer. In the plan view, a first edge forming part of edges of the emitter mesa layer extends in a first direction, and a second edge forming part of edges of the base electrode faces the first edge. A gap between the first edge and the second edge in a terminal portion located in an end portion of the emitter mesa layer in the first direction is wider than a gap in an intermediate portion of the emitter mesa layer.

A trench-gate power MOSFET with optimized layout, comprising: a substrate; a first semiconductor region formed on the substrate, having a first doping type; mutually separated trench isolation gate structure, formed on the first semiconductor region, the trench isolation gate structure includes an gate oxide layer and a gate electrode; a second semiconductor region and a third semiconductor region formed between any two adjacent structures of mutually separated trench isolation gate structures; and a first shielding region, formed under each of the third semiconductor regions, connecting simultaneously with multiple mutually separated trench isolation structures.

A main semiconductor device element is SiC-MOSFETs with a trench gate structure, the main semiconductor device element having main MOS regions responsible for driving the MOSFETs and main SBD regions that are regions responsible for SBD operation. The main MOS regions and the main SBD regions are adjacent to one another and each pair of a main MOS region and a main SBD region adjacent thereto share one trench. In the main SBD regions, first and second p-type regions, and Schottky electrodes at the front surface of the semiconductor substrate and forming Schottky junctions with an n.sup.−-type drift region are provided. The first p-type regions are provided along sidewalls of the trenches, in contact with the first p.sup.+-type regions at the bottoms of the trenches. The second p-type regions are provided between the first p-type regions and the Schottky electrodes, and are electrically connected to these regions.

The present disclosure relates to an electrostatic protection device including an SCR and a manufacturing method thereof. The electrostatic protection device includes a third N+ doped region across an N-type well region and a P-type well region, and a third P+ doped region adjacent to the third N+ doped region. Each of the third N+ doped region and the third P+ doped region has a high doping concentration. In a case that Zener breakdown occurs in a PN junction structure between the third N+ doped region and the third P+ doped region, the SCR is triggered to form a discharge current path. The present disclosure can reduce a trigger voltage of an electrostatic protection device including an SCR, and can provide electrostatic protection devices having different trigger voltages, with high stability and high robustness.

A vertical bipolar transistor device includes a heavily-doped semiconductor substrate, a first semiconductor epitaxial layer, at least one doped well, an isolation structure, and an external conductor. The heavily-doped semiconductor substrate and the doped well have a first conductivity type, and the first semiconductor epitaxial layer has a second conductivity type. The first semiconductor epitaxial layer is formed on the heavily-doped semiconductor substrate. The doped well is formed in the first semiconductor epitaxial layer. The isolation structure, formed in the heavily-doped semiconductor substrate and the first semiconductor epitaxial layer, surrounds the first semiconductor epitaxial layer and the at least one doped well. The external conductor is arranged outside the first semiconductor epitaxial layer and the doped well and electrically connected to the first semiconductor epitaxial layer and the doped well.

An avalanche-protected field effect transistor includes, within a semiconductor substrate, a body semiconductor layer and a doped body contact region having a doping of a first conductivity type, and a source region a drain region having a doping of a second conductivity type. A buried first-conductivity-type well may be located within the semiconductor substrate. The buried first-conductivity-type well underlies, and has an areal overlap in a plan view with, the drain region, and is vertically spaced apart from the drain region, and has a higher atomic concentration of dopants of the first conductivity type than the body semiconductor layer. The configuration of the field effect transistor induces more than 90% of impact ionization electrical charges during avalanche breakdown to flow from the source region, to pass through the buried first-conductivity-type well, and to impinge on a bottom surface of the drain region.

An integrated circuit includes a shallow P-type well (SPW) below a surface of a semiconductor substrate and a shallow N-type well (SNW) below the surface. The SPW forms an anode of a diode and the SNW forms a cathode of the diode. The SNW is spaced apart from the SPW by a well space region; and a thin field relief oxide structure lies over the well space region.

A layout structure of an ESD protection semiconductor device includes a substrate, a first doped region, a pair of second doped regions, a pair of third doped regions, at least a first gate structure formed within the first doped region, and a drain region and a first source region formed at two sides of the first gate structure. The substrate, the first doped region and the third doped regions include a first conductivity type. The second doped regions, the drain region and the first source region include a second conductivity type complementary to the first conductivity type. The first doped region includes a pair of lateral portions and a pair of vertical portions. The pair of second doped regions is formed under the pair of lateral portions, and the pair of third doped regions is formed under the pair of vertical portions.