A transistor having: a semiconductor; a first electrode in contact with the semiconductor; a second electrode in contact with the semiconductor; and a control electrode, disposed between the first electrode and the second electrode, for controlling a flow of carriers in a channel in the semiconductor between. the first electrode and the second electrode. A first electric field is produced in the channel in response to an electrical voltage applied between the first electrode and the second electrode. A field plate, comprising a resistive material, is disposed over the channel. A voltage source is connected across portions of the resistive field plate material for producing second electric field across such portions of the resistor, such second electric field being coupled into the channel to modify one or more peaks of the first electric field in the channel.

A semiconductor device includes a semiconductor substrate and a resistance element provided above the semiconductor substrate, the resistance element includes a conductive pattern using a gate electrode film formed simultaneously with a gate electrode film arranged on a side surface of a semiconductor nanowire of a VNW transistor, and there is fabricated the semiconductor device that includes the VNW transistor having the semiconductor nanowire and the resistance element having sufficient electrical resistance.

According to one embodiment, a semiconductor device includes first, second, and third electrodes, first, second, and third semiconductor regions, a plurality of ring-shaped regions, and a semi-insulating layer. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region surrounds the second semiconductor region, and is provided on the first semiconductor region. The ring-shaped regions surround the second semiconductor region. The second electrode is provided on the second semiconductor region. The third electrode is provided on the third semiconductor region. The semi-insulating layer contacts the first semiconductor region, the second electrode, the ring-shaped regions, and the third electrode. The ring-shaped regions include first and second ring-shaped regions provided between the first ring-shaped region and the third semiconductor region. A length of the second ring-shaped region in a diametrical direction is shorter than a length of the first ring-shaped region in the diametrical direction.

In an example, a semiconductor device includes an insulated gate transistor cell, a first region (e.g., a drain region and/or a drift region), a cathode region, a second region (e.g., an anode region and/or a separation region), and a source electrode. The insulated gate transistor cell includes a source region and a gate electrode. The source region and the cathode region are in a silicon carbide body. The gate electrode and the cathode region are electrically connected. The cathode region, the source region, and the first region have a first conductivity type. The second region has a second conductivity type and is between the cathode region and the first region. The source electrode and the source region are electrically connected. The source electrode and the second region are in contact with each other. A rectifying junction is electrically coupled between the source electrode and the cathode region.

Disclosed is a transistor device which includes a semiconductor body having a first surface, a source region, a drift region, a body region being arranged between the source region and the drift region, a gate electrode adjacent the body region and dielectrically insulated from the body region by a gate dielectric, and a field electrode adjacent the drift region and dielectrically insulated from the drift region by a field electrode dielectric, wherein the field electrode comprises a first layer and a second layer, wherein the first layer has a lower electrical resistance than the second layer, wherein a portion of the second layer is disposed above and directly contacts a portion of the first layer.

A semiconductor device includes a semiconductor substrate having a major surface and both an element-forming region and an outer peripheral voltage-withstanding region that are provided on the major surface side of the semiconductor substrate. The element-forming region includes both a cell region for forming a power element and a circuit element region for forming at least one circuit element. The circuit element region is interposed between the outer peripheral voltage-withstanding region and the cell region. The outer peripheral voltage-withstanding region includes a boundary region that adjoins the element-forming region. In the boundary region, there is provided one or more voltage-withstanding regions. At least one of the one or more voltage-withstanding regions has a withstand voltage lower than both the withstand voltages of the cell region and the circuit element region.

A laterally diffused metal oxide semiconductor structure can include: a base layer; a source region and a drain region located in the base layer; first dielectric layer located on a top surface of the base layer and adjacent to the source region; a voltage withstanding layer located on the top surface of the base layer and located between the first dielectric layer and the drain region; a first conductor at least partially located on the first dielectric layer; and a second conductor at least partially located on the voltage withstanding layer, where the first and second conductors are spatially isolated, and a juncture region of the first dielectric layer and the voltage withstanding layer is covered by one of the first and second conductors.

A high-voltage n-channel high electron mobility transistor (HEMT) device is provided. In view of a relatively high process difficulty in preparing super junctions on heterojunction devices such as HEMT, the high-voltage n-channel HEMT device provides a surface super junction structure for an n-channel HEMT device. A comb-finger-shaped p-type semiconductor strip block is prepared on a surface of a drift region of the high-voltage n-channel HEMT device, and the p-type semiconductor strip block is electrically connected to a source electrode, so that large-range depletion of a channel of the drift region is realized under a turn-off condition, and a depletion region tolerates a high voltage, thus enhancing a breakdown characteristic of the high-voltage re-channel HEMT device.

An oxide semiconductor device has an improved withstand voltage when an inverse voltage is applied, while suppressing diffusion of different types of materials to a Schottky interface. The oxide semiconductor device includes an n-type gallium oxide epitaxial layer, p-type oxide semiconductor layers of an oxide that is a different material from the material for the gallium oxide epitaxial layer, a dielectric layer formed to cover at least part of a side surface of the oxide semiconductor layer, an anode electrode, and a cathode electrode. Hetero pn junctions are formed between the lower surfaces of the oxide semiconductor layers and a gallium oxide substrate or between the lower surfaces of the oxide semiconductor layers and the gallium oxide epitaxial layer.

The semiconductor device includes: a fourth impurity layer disposed in a state of being connected to the outermost peripheral second impurity layer and being separated from the first impurity layer between the outermost peripheral second impurity layer and the first impurity layer of the terminal portion, the fourth impurity layer having a second conductivity type and having an impurity concentration lower than an impurity concentration of the second impurity layer; an insulating film disposed on at least a part of the terminal portion, the insulating film having a first opening on the first impurity layer; and an electrode disposed on the insulating film, the electrode connected to the first impurity layer via the first opening.