A method of processing semiconductor material includes applying an organosulfur solution to a top surface of a semiconductor material, the organosulfur solution having at least one organosulfur compound. The at least one organosulfur compound has at least one sulfur atom double bonded to a carbon atom and a pH of not less than 8. An organosulfur solution may be applied at temperatures above 25 C. to increase sulfur deposition rates and increase sulfur coverage on a surface of a semiconductor material.

A semiconductor structure is provided that contains a non-volatile battery which controls gate bias and has increased output voltage retention and voltage resolution. The semiconductor structure may include a semiconductor substrate including at least one channel region that is positioned between source/drain regions. A gate dielectric material is located on the channel region of the semiconductor substrate. A battery stack is located on the gate dielectric material. The battery stack includes, a cathode current collector located on the gate dielectric material, a cathode material located on the cathode current collector, a first ion diffusion barrier material located on the cathode material, an electrolyte located on the first ion diffusion barrier material, a second ion diffusion barrier material located on the electrolyte, an anode region located on the second ion diffusion barrier material, and an anode current collector located on the anode region.

A plurality of gate structures are formed straddling nFET semiconductor fins and pFET semiconductor fins which extend upwards from a surface of a semiconductor substrate. A boron-doped silicon germanium alloy material is epitaxially grown from exposed surfaces of both the nFET semiconductor fins and the pFET semiconductor fins not protected by the gate structures. An anneal is then performed. During the anneal, silicon and germanium from the boron-doped silicon germanium alloy material diffuse into the nFET semiconductor fins and act as an n-type dopant forming a junction in the nFET semiconductor fins. Since boron is a Group IIIA element it does not have any adverse effect. During the same anneal, boron from the boron-doped silicon germanium alloy material will diffuse into the pFET semiconductor fins to form a junction therein.

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.

A vertical semiconductor apparatus includes: a gallium nitride substrate; a gallium nitride semiconductor layer on the gallium nitride substrate; a p-type impurity region in the gallium nitride semiconductor layer and having an element to function as an acceptor for gallium nitride; an n-type impurity region in the p-type impurity region and having an element to function as a donor for gallium nitride; and an electrode provided contacting a rear surface of the gallium nitride substrate. The element to function as the donor in the n-type impurity region includes: a first impurity element to enter sites of gallium atoms in the gallium nitride semiconductor layer; and a second impurity element different from the first impurity element and to enter sites of nitrogen atoms in the gallium nitride semiconductor layer. In the n-type impurity region, a concentration of the first impurity element is higher than that of the second impurity element.

The present disclosure is related to a III-Nitride semiconductor device comprising a base substrate, a buffer layer, a channel layer, a barrier layer so that a 2-dimensional charge carrier gas is formed or can be formed near the interface between the channel layer and the barrier layer, and at least one set of a first and second electrode in electrical contact with the 2-dimensional charge carrier gas, wherein the device further comprises a mobile charge layer (MCL) within the buffer layer or near the interface between the buffer layer and the channel layer, when the device is in the on-state. The device further comprises an electrically conductive path between one of the electrodes and the mobile charge layer. The present disclosure is also related to a method for producing a device according to the present disclosure.

A substrate for semiconductor device includes a substrate, a reaction layer provided on a back surface of the substrate, a transmission preventing metal having a transmittance with respect to red light or infrared light lower than that of the substrate and a material of the substrate being mixed in the reaction layer, and a metal thin film layer formed on a back surface of the reaction layer and formed of the same material as the transmission preventing metal.

Provided is a semiconductor device including an enhancement mode (E-mode) high electron mobility transistor (HEMT). The E-mode HEMT includes a substrate, and a channel layer disposed on the substrate. A barrier structure disposed on the channel layer. A pair of source/drain (S/D) metals respectively disposed on the channel layer at opposite sides of the barrier structure. A gate metal disposed on the barrier structure between the pair of S/D metals. The channel layer has a two-dimensional electron gas (2DEG) layer close to an interface between the channel layer and the barrier structure. A fluorine ion concentration in the channel layer adjacent to the 2DEG layer is greater than that away from the 2DEG layer.

Fabrication of doped AlN crystals and/or AlGaN epitaxial layers with high conductivity and mobility is accomplished by, for example, forming mixed crystals including a plurality of impurity species and electrically activating at least a portion of the crystal.

A semiconductor device includes a codoped layer, a channel layer, a barrier layer, and a gate electrode disposed in a trench extending through the barrier layer and reaching a middle point in the channel layer via a gate insulating film. On both sides of the gate electrode, a source electrode and a drain electrode are formed. On the source electrode side, an n-type semiconductor region is disposed to fix a potential and achieve a charge removing effect while, on the drain electrode side, a p-type semiconductor region is disposed to improve a drain breakdown voltage. By introducing hydrogen into a region of the codoped layer containing Mg as a p-type impurity in an amount larger than that of Si as an n-type impurity where the n-type semiconductor region is to be formed, it is possible to inactivate Mg and provide the n-type semiconductor region.