Semiconductor devices comprising a getter material are described. The getter material can be located in or over the active region of the device and/or in or over a termination region of the device. The getter material can be a conductive or an insulating material. The getter material can be present as a continuous or discontinuous film. The device can be a SiC semiconductor device such as a SiC vertical MOSFET. Methods of making the devices are also described. Semiconductor devices and methods of making the same comprising source ohmic contacts formed using a self-aligned process are also described. The source ohmic contacts can comprise titanium silicide and/or titanium silicide carbide and can act as a getter material.

A high electron mobility transistor (HEMT) device with a highly resistive layer co-doped with carbon (C) and a donor-type impurity and a method for making the HEMT device is disclosed. In one embodiment, the HEMT device includes a substrate, the highly resistive layer co-doped with C and the donor-type impurity formed above the substrate, a channel layer formed above the highly resistive layer, and a barrier layer formed above the channel layer. In one embodiment, the highly resistive layer comprises gallium nitride (GaN). In one embodiment, the donor-type impurity is silicon (Si). In another embodiment, the donor-type impurity is oxygen (O).

A HEMT made of nitride semiconductor materials is disclosed. The HEMT includes the GaN channel layer, the InAlN barrier layer, and the n-type GaN regions formed beneath the source electrode and the drain electrode at a temperature such that the InAlN barrier layer in the crystal quality thereof is not degraded, lower than 800 C. The n-type GaN regions are doped with silicon (Si) and have a ratio of silicon atoms against carbon atoms (Si/C) greater than 100.

A semiconductor device includes a gate stack arranged on a channel region of a semiconductor layer and a semiconductor layer arranged on an insulator layer. A crystalline source/drain region is arranged in a cavity in the insulator layer, and a spacer is arranged adjacent to the gate stack, the spacer arranged over the source/drain region. A second insulator layer is arranged on the spacer and the gate stack, and a conductive contact is arranged in the source/drain region.

A high electron mobility transistor (HEMT) includes a silicon substrate, an unintentionally doped gallium nitride (UID GaN) layer over the silicon substrate. The HEMT further includes a donor-supply layer over the UID GaN layer, a gate structure, a drain, and a source over the donor-supply layer. The HEMT further includes a dielectric layer having one or more dielectric plug portions in the donor-supply layer and top portions between the gate structure and the drain over the donor-supply layer. A method for making the HEMT is also provided.

Semiconductor devices and manufacturing methods are provided for making channel and gate lengths independent from lithography. Also, semiconductor devices and manufacturing methods are provided for increasing resistivity between drain and channel to allow for higher voltage operation. For example, a semiconductor device includes a first doped layer implanted in a semiconductor substrate forming one of a source or a drain and a gate metal layer disposed over the first doped layer. The semiconductor device further includes a second doped layer disposed over the gate metal forming the other the source or the drain, where the first doped layer, the gate metal layer and the second doped layer form a vertical stack of layers of the semiconductor device. The semiconductor device further includes a conduction channel formed in a trench that extends vertically through the vertical stack of layers and terminates at the semiconductor substrate.

An integrated circuit device includes first and second fin-type active regions having different conductive type channel regions, a first device isolation layer covering both sidewalk of the first fin-type active region, and a second device isolation layer covering both sidewalls of the second fin-type active region. The first device isolation layer and the second device isolation layer have different stack structures. To manufacture the integrated circuit device, the first device isolation layer covering both sidewalls of the first fin-type active region and the second device isolation layer covering both sidewalk of the second fin-type active region are formed after the first fin-type active region and the second fin-type active region are formed. The first device isolation layer and the second device isolation layer are formed to have different stack structure.

A semiconductor device includes first channel layers disposed over a substrate, a first source/drain region disposed over the substrate, a gate dielectric layer disposed on and wrapping each of the first channel layers, a gate electrode layer disposed on the gate dielectric layer and wrapping each of the first channel layers, and a liner semiconductor layer disposed between the first channel layers and the first source/drain region.

A semiconductor power device includes a substrate, a channel layer, a barrier layer, a gate, a source, and a drain. The channel layer is located on the substrate. The barrier layer is located on the channel layer and includes a first region and a second region outside the first region. There is a first compound in the first region and a second compound in the second region. The first compound and the second compound each have an aluminum atom of a different ratio, and the aluminum composition ratio of the first compound is less than the aluminum composition ratio of the second compound. The ratio consists of a plurality of different atoms in the first compound and the second compound.

In some examples, a transistor comprises a gallium nitride (GaN) layer; a GaN-based alloy layer having a top side and disposed on the GaN layer, wherein source, drain, and gate contact structures are supported by the GaN layer, and a first doped region positioned in a drain access region and extending from the top side into the GaN layer.