A method of manufacturing a composite structure comprises: a) providing a donor substrate of a single-crystal semiconductor material, b) implanting ions into the donor substrate, excluding an annular peripheral region, to form a buried brittle plane, the implantation conditions defining a first thermal budget for obtaining bubbling on a face of the donor substrate and a second thermal budget for obtaining a fracture in the brittle plane, c) forming a stiffening film on the donor substrate, carried out by applying a thermal budget lower than the first thermal budget, the stiffening film being perforated in the form of a mesh, the perforated stiffening film leaving a plurality of zones of the front face bare, d) depositing a carrier substrate on the donor substrate carried out by applying a thermal budget greater than the first thermal budget, and e) separating the donor substrate along the brittle plane.

A method of manufacturing a composite structure comprises: a) providing a donor substrate of a single-crystal semiconductor material, b) implanting ions into the donor substrate, excluding an annular peripheral region, to form a buried brittle plane, the implantation conditions defining a first thermal budget for obtaining bubbling on a face of the donor substrate and a second thermal budget for obtaining a fracture in the brittle plane, c) forming a stiffening film on the donor substrate, carried out by applying a thermal budget lower than the first thermal budget, the stiffening film being perforated in the form of a mesh, the perforated stiffening film leaving a plurality of zones of the front face bare, d) depositing a carrier substrate on the donor substrate carried out by applying a thermal budget greater than the first thermal budget, and e) separating the donor substrate along the brittle plane.

A method of manufacturing a semiconductor device includes: injecting an inert element or an electron beam into a GaN-based semiconductor substrate; implanting magnesium into the GaN-based semiconductor substrate; and performing a heat treatment after the injecting and the implanting. A first implantation range of inert element or electron beam and a second implantation range of magnesium overlap with each other. A reference depth Dref (nm) calculated using a formula of Dref=D1+140 and a deepest injection depth D1 (nm) in the injecting is deeper than a deepest implantation depth D2 (nm) in the implanting. After the heat treatment, a concentration of magnesium decreases toward a deeper side at a predetermined decrease rate at a position of the reference depth Dref. The predetermined decrease rate is smaller than a decrease rate at which a concentration of magnesium becomes 1/10 per depth of 300 nm.

A semiconductor structure and a manufacturing method thereof are provided. The manufacturing method of the semiconductor structure includes: epitaxially growing a semiconductor material among at least two channel layers; implanting pnictogen dopants in the semiconductor material; implanting chalcogen dopants in the semiconductor material; annealing the semiconductor material with the chalcogen dopants; forming a bottom contact etching stop layer (BCESL) on the semiconductor material with the chalcogen dopants; and etching the BCESL and forming a metal layer above the semiconductor material.