An upper layer (4,5) made of non-doped III-V compound semiconductor is formed on a lower layer (3) made of non-doped III-V compound semiconductor. Impurity source gas is fed through vapor phase diffusion using an organometallic vapor-phase epitaxy device to add an impurity to the upper layer (4,5). The vapor phase diffusion is continued with the feed of the impurity source gas stopped or with a feed amount of the impurity source gas lowered.

A manufacturing method of a vertical GaN-based semiconductor device having: a GaN-based semiconductor substrate; a GaN-based semiconductor layer including a drift region having doping concentration of an n type impurity, which is lower than that of the GaN-based semiconductor substrate, and is provided on the GaN-based semiconductor substrate; and MIS structure having the GaN-based semiconductor layer, an insulating film contacting the GaN-based semiconductor layer, and a conductive portion contacting the insulating film, the method includes: implanting an n type dopant in a back surface of the GaN-based semiconductor substrate after forming of the MIS structure, and annealing the GaN-based semiconductor substrate after the implanting of the n type dopant.

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 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.

An upper layer (4,5) made of non-doped III-V compound semiconductor is formed on a lower layer (3) made of non-doped III-V compound semiconductor. Impurity source gas is fed through vapor phase diffusion using an organometallic vapor-phase epitaxy device to add an impurity to the upper layer (4,5). The vapor phase diffusion is continued with the feed of the impurity source gas stopped or with a feed amount of the impurity source gas lowered.

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 forming doped regions by diffusion in gallium nitride materials includes providing a substrate structure including a gallium nitride layer and forming a mask on the gallium nitride layer. The mask exposes one or more portions of a top surface of the gallium nitride layer. The method also includes depositing a magnesium-containing gallium nitride layer on the one or more portions of the top surface of the gallium nitride layer and concurrently with depositing the magnesium-containing gallium nitride layer, forming one or more magnesium-doped regions in the gallium nitride layer by diffusing magnesium into the gallium nitride layer through the one or more portions. The magnesium-containing gallium nitride layer provides a source of magnesium dopants. The method further includes removing the magnesium-containing gallium nitride layer and removing the mask.

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.

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 semiconductor device includes a substrate; a first nitride semiconductor layer above the substrate; a second nitride semiconductor layer on the first nitride semiconductor layer; an ohmic electrode above the substrate; and a contact layer in contact with at least a part of the ohmic electrode, the contact layer containing silicon and chlorine. The second nitride semiconductor layer has a wider band gap than the first nitride semiconductor layer. A two-dimensional electron gas channel is formed in the first nitride semiconductor layer at a heterointerface between the first nitride semiconductor layer and the second nitride semiconductor layer. A silicon concentration has a higher peak value than a chlorine concentration in the contact layer.