There is provided a semiconductor device, including: a substrate; a group III nitride layer on the substrate, the group III nitride layer containing group III nitride; and a recess on the group III nitride layer, the group III nitride layer including: a channel layer, and a barrier layer on the channel layer, thereby forming a two-dimensional electron gas in the channel layer, the barrier layer including: a first layer containing aluminum gallium nitride, and a second layer on the first layer, the second layer containing aluminum gallium nitride added with an n-type impurity, wherein the recess is formed by removing all or a part of a thickness of the second layer, and at least a part of a thickness of the first layer is arranged below the recess.

An integrated circuit structure comprises a relaxed buffer stack that includes a channel region, wherein the relaxed buffer stack and the channel region include a group III-N semiconductor material, wherein the relaxed buffer stack comprises a plurality of AlGaN material layers and a buffer stack is located over over the plurality of AlGaN material layers, wherein the buffer stack comprises the group III-N semiconductor material and has a thickness of less than approximately 25 nm. A back barrier is in the relaxed buffer stack between the plurality of AlGaN material layers and the buffer stack, wherein the back barrier comprises an AlGaN material of approximately 2-10% Al. A polarization stack over the relaxed buffer stack.

A method of forming a high electron mobility transistor (HEMT) includes: providing a semiconductor structure comprising a channel layer and a barrier layer sequentially stacked on a substrate; forming a first insulating layer on the barrier layer; and forming a gate contact, a source contact, and a drain contact on the barrier layer. An interface between the first insulating layer and the barrier layer comprises a modified interface region on a drain access region and/or a source access region of the semiconductor structure such that a sheet resistance of the drain access region and/or the source access region is between 300 and 400 Ω/sq.

Methods for fabricating vertical cavity surface emitting lasers (VCSELs) on a large wafer are provided. An un-patterned epi layer form is bonded onto a first reflector form. The first reflector form includes a first reflector layer and a wafer of a first substrate type. The un-patterned epi layer form includes a plurality of un-patterned layers on a wafer of a second substrate type. The first and second substrate types have different thermal expansion coefficients. A resulting bonded blank is substantially non-varying in a plane that is normal to an intended emission direction of the VCSEL. A first regrowth is performed to form first regrowth layers, some of which are patterned to form a tunnel junction pattern. A second regrowth is performed to form second regrowth layers. A second reflector form is bonded onto the second regrowth layers, wherein the second reflector form includes a second reflector layer.

A production apparatus for producing a structural body includes: a holding mechanism that holds a processing target in contact with an etching solution, the processing target including an etch region that is made of a Group III nitride, and on which photoelectrochemical etching is to be performed; a light emitting device that irradiates the processing target with first light for performing the photoelectrochemical etching; a light emitting device that irradiates the processing target with second light that has a wavelength longer than that of the first light; and a measurement device that measures reflected light resulting from the second light being reflected off a surface of the etch region.

A power amplifier comprising a GaN-based high electron mobility transistor (HEMT) device, wherein a power added efficiency (PAE) of the power amplifier is greater than 32% at P1DB during operation of the power amplifier between 26.5 GHz and 30.5 GHz.

The present disclosure provides a high electron mobility transistor (HEMT) including a substrate; a buffer layer over the substrate; a GaN layer over the buffer layer; a first AlGaN layer over the GaN layer; a first AlN layer over the first AlGaN layer; a p-type GaN layer over the first AlN layer; and a second AlN layer on the p-type GaN layer.

A bipolar transistor including a first collector layer, a second collector layer, a base layer, and an emitter layer is disposed on a substrate. Etching characteristics of the second collector layer are different from etching characteristics of the first collector layer and the base layer. In plan view, an edge of an interface between the first collector layer and the second collector layer is disposed inside an edge of a lower surface of the base layer, and an edge of an upper surface of the second collector layer coincides with the edge of the lower surface of the base layer or is disposed inside the edge of the lower surface of the base layer.

Fabricating a regrown GaN p-n junction includes depositing a n-GaN layer on a substrate including n.sup.+-GaN, etching a surface of the n-GaN layer to yield an etched surface, depositing a p-GaN layer on the etched surface, etching a portion of the n-GaN layer and a portion of the p-GaN layer to yield a mesa opposite the substrate, and passivating a portion of the p-GaN layer around an edge of the mesa. The regrown GaN p-n junction is defined at an interface between the n-GaN layer and the p-GaN layer. The regrown GaN p-n junction includes a substrate, a n-GaN layer on the substrate having an etched surface, a p-GaN layer on the etched surface, a mesa defined by an etched portion of the n-GaN layer and an etched portion of the p-GaN layer, and a passivated portion of the p-GaN layer around an edge of the mesa.

A circuit element is formed on a substrate made of a compound semiconductor. A bonding pad is disposed on the circuit element so as to at least partially overlap the circuit element. The bonding pad includes a first metal film and a second metal film formed on the first metal film. A metal material of the second metal film has a higher Young's modulus than a metal material of the first metal film.