A semiconductor device includes a substrate including a first main surface; a semiconductor layer provided on the first main surface of the substrate; an electrically insulating layer provided on the semiconductor layer; a source electrode and a drain electrode that are provided on the semiconductor layer; and a gate electrode provided on the electrically insulating layer. The semiconductor layer has an electron transport layer provided on the substrate and including a first upper surface, and has an electron supply layer provided on the electron transport layer. A first opening and a second opening are each formed in the electron supply layer and the electron transport layer. A third opening connected to the first opening and a fourth opening connected to the second opening are each formed in the electrically insulating layer.

A nitride semiconductor device includes a substrate, a first electron transport layer above the substrate, a first electron supply layer above the first electron transport layer, a first nitride semiconductor layer above the first electron supply layer, a first opening passing through the first nitride semiconductor layer and the first electron supply layer and reaching the first electron transport layer, a second electron transport layer disposed above the first nitride semiconductor layer and along the inner surface of the first opening, a second electron supply layer disposed above the second electron transport layer and covering the first opening, a gate electrode disposed above the second electron supply layer and covering the first opening, a source electrode connected to the first nitride semiconductor layer and the second electron transport layer, and a drain electrode.

The invention relates to a lateral field effect transistor, in particular a HEMT having a heterostructure, in a III/V semiconductor system with a p-type semiconductor being arranged between an ohmic load contact, in particular a drain contact, and a gate contact of the transistor for an injection of holes into a portion of the transistor channel. Further, a recombination zone implemented by a floating ohmic contact is provided for to improve the device performance.

The present disclosure provides a semiconductor structure and a manufacturing method therefor. In the semiconductor structure, a semiconductor substrate, a heterojunction and an in-situ insulation layer are disposed from bottom to top, a trench is provided in the in-situ insulation layer, and a transition layer is located on at least an in-situ insulation layer, the p-type semiconductor layer is located in the trench and on the gate region of the transition layer, and the heavily doped n-type layer is located on at least one of the p-type semiconductor layer in the gate region, the source region of the heterojunction, or the drain region of the heterojunction.

A semiconductor device includes at least one active region, a first dielectric layer, a gate structure, and an air void. The active region includes a III-V compound semiconductor layer. The first dielectric layer is disposed on the active region. The gate structure is disposed on the active region, and at least a part of the gate structure is disposed in the first dielectric layer. The air void is disposed in the first dielectric layer, and at least a part of the air void is disposed at two opposite sides of the gate structure in a horizontal direction.

We disclose a III-nitride semiconductor based heterojunction power device comprising: a first heterojunction transistor formed on a substrate, the first heterojunction transistor comprising: a first III-nitride semiconductor region formed over the substrate, wherein the first III-nitride semiconductor region comprises a first heterojunction comprising at least one two dimensional carrier gas; a first terminal operatively connected to the first III-nitride semiconductor region; a second terminal laterally spaced from the first terminal and operatively connected to the first III-nitride semiconductor region; a first plurality of highly doped semiconductor regions of a first polarity formed over the first III-nitride semiconductor region, the first plurality of highly doped semiconductor regions being formed between the first terminal and the second terminal; a first gate region operatively connected to the first plurality of highly doped semiconductor regions; and a second heterojunction transistor formed on the substrate. The second heterojunction transistor comprises: a second III-nitride semiconductor region formed over the substrate, wherein the second III-nitride semiconductor region comprises a second heterojunction comprising at least one two dimensional carrier gas; a third terminal operatively connected to the second III-nitride semiconductor region; a fourth terminal laterally spaced from the third terminal in the first dimension and operatively connected to the second III-nitride semiconductor region; a second gate region being formed over the second III-nitride semiconductor region, and between the third terminal and the fourth terminal. One of the first and second heterojunction transistors is an enhancement mode field effect transistor and the other of the first and second heterojunction transistors is a depletion mode field effect transistor.

According to one embodiment, a nitride semiconductor includes a base body, a nitride member, and an intermediate region provided between the base body and the nitride member. The nitride member includes a first nitride region including Al.sub.x1Ga.sub.1-x1N (0<x1≤1), and a second nitride region including Al.sub.x2Ga.sub.1-x2N (0≤x2<1, x2<x1). The first nitride region is between the intermediate region and the second nitride region. The intermediate region includes nitrogen and carbon. A concentration of carbon in the intermediate region is not less than 1.5×10.sup.19/cm.sup.3 and not more than 6×10.sup.20/cm.sup.3.

Provided herein are a wide-bandgap semiconductor bipolar charge trapping (BCT) non-volatile memory structure with only one single insulating layer and a fabrication method thereof. Monolithically integrated enhancement-mode (E-mode) n-channel and p-channel field effect transistors (n-FETs and p-FETs) for gallium nitride (GaN)-based complementary logic (CL) gates based on the proposed memory structure, together with a fabrication method thereof in a single process run and various logic circuits incorporating one or more of the GaN-based CL gates, are also provided herein.

A method for etching at least one layer of a gallium nitride (GaN)-based material is provided, the method including: providing the GaN-based layer having a front face; and at least one cycle including the following successive steps: modifying, by implanting hydrogen (H)- and/or helium (He)-based ions, at least some of a thickness of the GaN-based layer to form in the layer at least one modified portion extending from the front face, the implanting being carried out from a plasma, the modifying by implanting being carried out such that the modified portion extends from the front face and over a depth greater than 3 nm; oxidizing at least some of the modified portion by exposing the layer to an oxygen-based plasma, to define in the layer, at least one oxidized portion and at least one non-oxidized portion; and etching the oxidized portion selectively at the non-oxidized portion.

According to one embodiment, a semiconductor device includes a substrate, and a first semiconductor layer including magnesium and Al.sub.x1Ga.sub.1-x1N. The first semiconductor layer includes first, second, and third regions. The first region is between the substrate and the third region. The second region is between the first and third regions. A first concentration of magnesium in the first region is greater than a third concentration of magnesium in the third region. A second concentration of magnesium in the second region decreases along a first orientation. The first orientation is from the substrate toward the first semiconductor layer. A second change rate of a logarithm of the second concentration with respect to a change of a position along the first orientation is greater than a third change rate of a logarithm of the third concentration with respect to the change of the position along the first orientation.