A nitride semiconductor device 1 includes a first transistor 3 which is constituted of a normally-off transistor and functions as a main transistor and a second transistor 4 which is constituted of a normally-on transistor and arranged to limit a gate current of the first transistor. The first transistor 3 includes a first electron transit layer 7A constituted of a nitride semiconductor and a first electron supply layer 8A which is formed on the first electron transit layer and constituted of a nitride semiconductor. The second transistor 4 includes a second electron transit layer 7B constituted of a nitride semiconductor and a second electron supply layer 8B which is formed on the second electron transit layer and constituted of a nitride semiconductor. A gate electrode 51 and a source electrode 44 of the second transistor 4 are electrically connected to a gate electrode 16 of the first transistor 3.

A semiconductor device includes a plurality of tunnel diodes, each of which includes a first semiconductor region of a first conductive type and a second semiconductor region of a second conductive type that is provided above the first semiconductor region, the second semiconductor region being a nanowire shape; an insulating film provided around a side surface of the second semiconductor region; a plurality of first electrodes, each coupled to the first semiconductor region; and a plurality of second electrodes, each coupled to the second semiconductor region, wherein the second electrode has a first surface that faces the side surface of the second semiconductor region across the insulating film, and a diameter of a second semiconductor region of a first tunnel diode of the plurality of tunnel diodes is different from a diameter of a second semiconductor region of a second tunnel diode.

An active device substrate includes a substrate, a first semiconductor layer, a gate insulating layer, a first gate, a first source, a first drain and a shielding electrode. The first semiconductor layer includes a first heavily doped region, a first lightly doped region, a channel region, a second lightly doped region, and a second heavily doped region that are sequentially connected. The first gate is located on the gate insulating layer and overlaps the channel region. The first source is electrically connected to the first heavily doped region. The first drain is electrically connected to the second heavily doped region. The shielding electrode overlaps the second lightly doped region in a normal direction of the substrate.

A high electron mobility transistor includes a channel layer; a barrier layer on the channel layer and having an energy bandgap greater than an energy bandgap of the channel layer; a gate structure on the barrier layer; a source electrode and a drain electrode spaced apart from each other on the barrier layer with the gate structure therebetween; a field plate electrically connected to the source electrode and extending above the gate structure; and a field dispersion layer in contact with the barrier layer and the drain electrode. The field dispersion layer may extend toward the gate structure.

A high electron mobility transistor (HEMT) includes a carrier transit layer, a carrier supply layer, a main gate, a control gate, a source electrode and a drain electrode. The carrier transit layer is on a substrate. The carrier supply layer is on the carrier transit layer. The main gate and the control gate are on the carrier supply layer. A fluoride ion doped region is formed right below the main gate in the carrier supply layer. The source electrode and the drain electrode are at two opposite sides of the main gate and the control gate, wherein the source electrode is electrically connected to the control gate by a metal interconnect. The present invention also provides a method of forming a high electron mobility transistor (HEMT).

A semiconductor device includes a III-V compound semiconductor layer, a III-V compound barrier layer, a gate trench, and a p-type doped III-V compound layer. The III-V compound barrier layer is disposed on the III-V compound semiconductor layer. The gate trench is disposed in the III-V compound barrier layer. The p-type doped III-V compound layer is disposed in the gate trench, and a top surface of the p-type doped III-V compound layer and a top surface of the III-V compound barrier layer are substantially coplanar.

A transistor includes a source contact connected to a Through-Silicon Via (TSV). A drain contact is connected to a first pad. A gate structure is interposed between the source contact and the drain contact. A second pad is connected to the gate structure, the second pad comprising a first side diametrically opposed to a second side, and a third side interposed therebetween, the source contact proximal to the third side, a first portion of the first side and a second portion of the second side.

The present disclosure provides an electrostatic discharge protection device, and relates to the technical field of semiconductors. A first P-type heavily-doped region and a first N-type heavily-doped region of the electrostatic discharge protection device are located in a P well, a second P-type heavily-doped region and a third N-type heavily-doped region are located in a first N well, one part of a second N-type heavily-doped region is located in the P well, the other part is located in the first N well, and the P well and the first N well are located in a P-type substrate. The P-type substrate is provided with a gate structure, the gate structure, the first N-type heavily-doped region, and the second N-type heavily-doped region form a transistor, the first N-type heavily-doped region and the gate structure are connected to a first voltage.

A semiconductor device comprises a substrate, a semiconductor layer formed on the substrate; and a high-voltage termination. The high-voltage termination includes a plurality of floating field rings, a deep trench and a dielectric material is disposed within the deep trench. The plurality of floating field rings are formed in the semiconductor layer and respectively disposed around a region of the semiconductor layer. The deep trench is formed in the semiconductor layer and concentrically disposed around an outermost floating field ring of the plurality of floating field rings. The high-voltage termination may also include a field plate disposed over the floating field rings, the deep trench, or both.

A resistor-transistor-logic circuit with GaN structures, including a 2DEG resistor having a drain connected with an operating voltage, and a logic FET having a gate connected to an input voltage, a source grounded and a drain connected with a source of the 2DEG resistor and connected collectively to an output voltage.