A semiconductor device according to an embodiment may include a board, an insulation layer disposed on the board, a threshold voltage control layer disposed on the insulation layer, a first semiconductor layer disposed on the threshold voltage control layer, and a second semiconductor layer disposed on the threshold voltage control layer to cover a portion of the first semiconductor layer. A negative differential resistance device according to an embodiment has an advantageous effect in that the gate voltage enables a peak voltage to be freely controlled within an operation range of the device by forming the threshold voltage control layer.

A semiconductor device includes a semiconductor part, first to fourth electrodes, first and second insulating films. The semiconductor part includes a first layer of a first conductivity type and a second layer of a second conductivity type. The first and second electrodes are provided on back and front surfaces of the semiconductor part, respectively. The second layer is provided between the first layer and the second electrode. A plurality of the third electrodes extend into the first layer through the second layer. The fourth electrode extends into the first layer from the front side of the semiconductor part and surrounds the second layer. The first insulating film electrically insulates the third electrode from the semiconductor part. The second insulating film electrically insulates the fourth electrode from the semiconductor part. The second insulating film has a first thickness greater than a second thickness of the first insulating film.

A laterally-diffused metal-oxide semiconductor, “LDMOS”, device and a method of making the same. The device includes a gate located on a major surface of a semiconductor die, a source region located in the die on a first side of the gate, a drain drift region located in the die on a second side of the gate opposite the first side, a first spacer located adjacent to a first sidewall of the gate on the first side of the gate, and a second spacer located adjacent to a second sidewall of the gate on the second side of the gate. The second spacer is located between the gate and the drain drift region. The second spacer comprises a proximal spacer portion and a distal spacer portion. The proximal spacer portion is located between the gate and the distal spacer portion. The proximal spacer portion and the distal spacer portion define a recess.

The present invention relates to a Semiconductor device including a first electrode, a second electrode and at least one semiconductor material or layer between the first and second electrode. The semiconductor device further includes at least one field plate structure for increasing a breakdown voltage of the semiconductor device. The at least one field plate structure comprises at least two recesses in the at least one semiconductor material or layer, the at least two recesses defining a semiconductor region therebetween, and a third electrode contacting or provided on the semiconductor region.

The present invention discloses a System on Chip, which includes a power supply pin, a ground pin, an anti-static unit and an anti-reverse connection unit, wherein the anti-static unit is connected between the power supply pin and the ground pin through the anti-reverse connection unit, the power supply pin and the ground pin of the System on Chip are connected to an external power supply; wherein, when the System on Chip is in normal operation, the anti-static unit performs ESD protection of the power supply pin through the conducted anti-static unit; whereas when the external power supply is reversely connected between the power supply pin and the ground pin of the System on Chip, the anti-reverse connection unit is cut off to prevent the reversely connected external power supply from directly connecting anode with cathode of the external power supply through the anti-static unit.

A Schottky barrier diode 1 includes: a semiconductor substrate made of gallium oxide; a drift layer made of gallium oxide; an anode electrode brought into Schottky contact with an upper surface of the drift layer; and a cathode electrode brought into ohmic contact with a lower surface of the semiconductor substrate. A ring-shaped outer peripheral trench is formed in the upper surface of the drift layer, and the anode electrode is partly filled in the outer peripheral trench. A ring-shaped back surface trench is formed in the lower surface of the semiconductor substrate such that the bottom thereof reaches the drift layer. This limits a current path to the area surrounded by the back surface trench, thereby mitigating electric field concentration in the vicinity of the bottom of the outer peripheral trench.

A Schottky barrier diode includes a semiconductor substrate made of gallium oxide, a drift layer made of gallium oxide and provided on the semiconductor substrate, an anode electrode brought into Schottky contact with the drift layer, and a cathode electrode brought into ohmic contact with the semiconductor substrate. The drift layer has a plurality of trenches formed in a position overlapping the anode electrode in a plan view. Among the plurality of trenches, a trench positioned at the end portion has a selectively increased width. Thus, the curvature radius of the bottom portion of the trench is increased, or an edge part constituted by the bottom portion as viewed in a cross section is divided into two parts. As a result, an electric field to be applied to the bottom portion of the trench positioned at the end portion is mitigated, making dielectric breakdown less likely to occur.

Devices, methods and techniques are disclosed to suppress electrical discharge and breakdown in insulating or encapsulation material(s) applied to solid-state devices. In one example aspect, a multi-layer encapsulation film includes a first layer of a first dielectric material and a second layer of a second dielectric material. An interface between the first layer and the second layer is configured to include molecular bonds to prevent charge carriers from crossing between the first layer and the second layer. The multi-layer encapsulation configuration is structured to allow an electrical contact and a substrate of the solid-state device to be at least partially surrounded by the multi-layer encapsulation configuration.

An IGBT and a manufacturing method therefor, wherein a target region in the IGBT is doped with first ions; the target region comprises at least one of a P-type substrate (11), a P-type well region (13), and a P-type source region (14); and the diffusion coefficient of the first ions is greater than the diffusion coefficients of boron ions. A PN junction formed by means of the present invention is a gradual junction, thereby improving breakdown voltage, shortening turn-off time, and improving anti-latch capability.

The present invention provides a DMOS device and a manufacturing method thereof. The DMOS device includes: a substrate, an epitaxial layer, a high voltage well, a body region, a gate, a source, a drain, a drift buried region and a buried region. A first PN junction is formed between the high voltage well and an upper surface of the substrate. From a cross-section view, along the channel direction, a second PN junction is formed between the drift buried region and the buried region or formed between the high voltage well and the buried region. Along the channel direction, the first PN junction and the second PN junction have respective depths. The depth is defined as a distance extending from the upper face of the epitaxial layer downward along a vertical direction. The depth of the second PN junction is shallower than the depth of the first PN junction.