An Enhancement-Mode HEMT having a gate electrode with a doped, Group III-N material disposed between an electrically conductive gate electrode contact and a gate region of the Enhancement-Mode HEMT, such doped, Group III-N layer increasing resistivity of the Group III-N material to deplete the 2DEG under the gate at zero bias.

A method of manufacturing a High-Electron-Mobility Transistor (HEMT) includes: preparing a substrate; forming a first buffer over the substrate; forming a second buffer over the first buffer, wherein forming the second buffer includes doping a first thickness of a material such as gallium nitride (GaN) with a first concentration of a dopant such as carbon, and doping a second thickness of the material with a second concentration of the dopant such that the second concentration of dopant has a gradient though the second thickness which progressively decreases in a direction away from the first thickness; forming a channel layer such as a GaN channel over the second buffer; forming a barrier layer such as aluminum gallium nitride (AlGaN) over the channel layer; and forming drain, source and gate terminals for the HEMT.

Depositing gallium nitride and carbon (GaN:C) (e.g., in the form of composite layers) when forming a gallium nitride drain of a transistor provides a buffer between the gallium nitride of the drain and silicon of a substrate in which the drain is formed. As a result, gaps and other defects caused by lattice mismatch are reduced, which improves electrical performance of the drain. Additionally, current leakage into the substrate is reduced, which further improves electrical performance of the drain. Additionally, or alternatively, implanting silicon in an aluminum nitride (AlN) liner for a gallium nitride drain reduces contact resistance at an interface between the gallium nitride and the silicon. As a result, electrical performance of the transistor is improved.

A manufacturing method of a group III-V compound semiconductor device, the method includes: a first process in which a group V material gas and an impurity material gas are supplied to a reacting furnace which is set at a first temperature of a range from 400° C. to 500° C. and a first pressure of a range from 100 hPa to 700 hPa, and impurities are doped in an undoped group III-V compound semiconductor layer, and a second process in which the supply of the impurity material gas is stopped, a temperature of the reacting furnace is raised to a second temperature which is higher than the first temperature, a pressure of the reacting furnace is set lower than a pressure of the first pressure, a supply of an etching gas is initiated and the supply of the group V material gas is continued.

A semiconductor device according to an embodiment includes a nitride semiconductor layer; an insulating layer; a first region disposed between the nitride semiconductor layer and the insulating layer and containing at least one element of hydrogen and deuterium; and a second region disposed in the nitride semiconductor layer, adjacent to the first region, and containing fluorine.

A nitride semiconductor device includes: a substrate; a first nitride semiconductor layer; a second nitride semiconductor layer having a greater band gap than the first nitride semiconductor layer; a source electrode and a drain electrode on the second nitride semiconductor layer apart from each other; a third nitride semiconductor layer, between the source electrode and the drain electrode, containing a p-type first impurity and serving as a gate; and a fourth nitride semiconductor layer, between the third nitride semiconductor layer and the drain electrode, containing a p-type second impurity, wherein the average carrier concentration of the fourth nitride semiconductor layer is lower than the average carrier concentration of the third nitride semiconductor layer.

An Enhancement-Mode HEMT having a gate electrode with a doped, Group III-N material disposed between an electrically conductive gate electrode contact and a gate region of the Enhancement-Mode HEMT, such doped, Group III-N layer increasing resistivity of the Group III-N material to deplete the 2DEG under the gate at zero bias.

Methods are provided of selectively obtaining n-type and p-type regions from the same III-Nitride layer deposited on a substrate without using diffusion or ion-implantation techniques. The III-Nitride layer is co-doped simultaneously with n-type and p-type dopants, with p-type dopant concentration higher than n-type dopant to generate p-n junctions. The methods rely on obtaining activated p-type dopants only in selected regions to generate p-type layers, whereas the rest of the regions effectively behave as an n-type layer by having deactivated p-type dopant atoms.

A method for forming an overlap transistor includes forming a gate structure over a III-V material, wet cleaning the III-V material on side regions adjacent to the gate structure and plasma cleaning the III-V material on the side regions adjacent to the gate structure. The III-V material is plasma doped on the side regions adjacent to the gate structure to form plasma doped extension regions that partially extend below the gate structure.

A semiconductor device includes a base substrate, a doped region at an upper surface of the base substrate, and a transistor over the upper surface of the base substrate and formed from a plurality of epitaxially-grown semiconductor layers. The doped region includes one or more ion species, and has a lower boundary above a lower surface of the base substrate. The base substrate may be a silicon substrate, and the transistor may be a GaN HEMT formed from a plurality of heteroepitaxial layers that include aluminum nitride and/or aluminum gallium nitride. The doped region may be a diffusion barrier region and/or an enhanced resistivity region. The ion species may be selected from phosphorus, arsenic, antimony, bismuth, argon, helium, nitrogen, and oxygen. When the ion species includes oxygen, the doped region may include a silicon dioxide layer formed from annealing the doped region after introduction of the oxygen.