Method for transferring a useful layer onto a supporting substrate, comprising the successive steps: a) providing a donor substrate made of crystalline diamond; b) implanting gaseous species, through the first surface of the donor substrate, according to a given implantation dose and implantation temperature suitable for forming a graphitic flat zone; c) assembling the donor substrate to the supporting substrate by direct adhesion; d) applying thermal annealing according to a thermal budget suitable for fracturing the donor substrate along the graphitic flat zone; the annealing temperature being greater than or equal to 800° C.; the implantation temperature is: above a minimum temperature beyond which bubbling of the implanted gaseous species occurs on the first surface when the donor substrate is submitted, in the absence of a stiffening effect, to thermal annealing according to said thermal budget, below a maximum temperature beyond which the given implantation dose no longer allows formation of the graphitic flat zone.

The present invention is related to a substrate (10) for a controlled implantation of ions (80) into a bulk (20), the substrate (10) comprising the bulk (20) composed of a crystalline first material (70), the bulk (20) comprising an implantation region (28) and a surface (22), wherein the implantation region (28) is located within the bulk (20) and along an implantation direction (82) at an implantation depth (26) below an implantation area (24) on the surface (10) of the bulk (20). Further, the present invention is related to a method of preparing a substrate (10) for a controlled implantation of ions (80) into a bulk (20), preferably the aforementioned substrate (10), the substrate (10) comprising the bulk (20) composed of a crystalline first material (70), the bulk (20) comprising an implantation region (28) and the surface (22), wherein the implantation region (28) is located within the bulk (20) and along an implantation direction (82) at an implantation depth (26) below an implantation area (24) on the surface (22) of the bulk (20).

The present invention is related to a substrate (10) for a controlled implantation of ions (80) into a bulk (20), the substrate (10) comprising the bulk (20) composed of a crystalline first material (70), the bulk (20) comprising an implantation region (28) and a surface (22), wherein the implantation region (28) is located within the bulk (20) and along an implantation direction (82) at an implantation depth (26) below an implantation area (24) on the surface (10) of the bulk (20). Further, the present invention is related to a method of preparing a substrate (10) for a controlled implantation of ions (80) into a bulk (20), preferably the aforementioned substrate (10), the substrate (10) comprising the bulk (20) composed of a crystalline first material (70), the bulk (20) comprising an implantation region (28) and the surface (22), wherein the implantation region (28) is located within the bulk (20) and along an implantation direction (82) at an implantation depth (26) below an implantation area (24) on the surface (22) of the bulk (20).

A method for fabricating an electrically isolated diamond nanowire includes forming a diamond nanowire on a diamond substrate, depositing a dielectric or a polymer on the diamond nanowire and on the diamond substrate, planarizing the dielectric or the polymer, etching a portion of the planarized dielectric or polymer to expose a first portion of the diamond nanowire, depositing a metal layer to conformably cover the first portion of the diamond nanowire, and implanting ions into a second portion of the diamond nanowire between the first portion of the diamond nanowire and the diamond substrate or at an intersection of the diamond nanowire and the diamond substrate, wherein the ions are implanted at an oblique angle from a first side of the diamond nanowire.

A method for fabricating an electrically isolated diamond nanowire includes forming a diamond nanowire on a diamond substrate, depositing a dielectric or a polymer on the diamond nanowire and on the diamond substrate, planarizing the dielectric or the polymer, etching a portion of the planarized dielectric or polymer to expose a first portion of the diamond nanowire, depositing a metal layer to conformably cover the first portion of the diamond nanowire, and implanting ions into a second portion of the diamond nanowire between the first portion of the diamond nanowire and the diamond substrate or at an intersection of the diamond nanowire and the diamond substrate, wherein the ions are implanted at an oblique angle from a first side of the diamond nanowire.

A method for fabricating an electrically isolated diamond nanowire includes forming a diamond nanowire on a diamond substrate, depositing a dielectric or a polymer on the diamond nanowire and on the diamond substrate, planarizing the dielectric or the polymer, etching a portion of the planarized dielectric or polymer to expose a first portion of the diamond nanowire, depositing a metal layer to conformably cover the first portion of the diamond nanowire, and implanting ions into a second portion of the diamond nanowire between the first portion of the diamond nanowire and the diamond substrate or at an intersection of the diamond nanowire and the diamond substrate, wherein the ions are implanted at an oblique angle from a first side of the diamond nanowire.

A method for fabricating an electrically isolated diamond nanowire includes forming a diamond nanowire on a diamond substrate, depositing a dielectric or a polymer on the diamond nanowire and on the diamond substrate, planarizing the dielectric or the polymer, etching a portion of the planarized dielectric or polymer to expose a first portion of the diamond nanowire, depositing a metal layer to conformably cover the first portion of the diamond nanowire, and implanting ions into a second portion of the diamond nanowire between the first portion of the diamond nanowire and the diamond substrate or at an intersection of the diamond nanowire and the diamond substrate, wherein the ions are implanted at an oblique angle from a first side of the diamond nanowire.

A method for improving doping uniformity in a semiconductor substrate, including placing the semiconductor substrate in an epitaxial growth chamber, performing an epitaxial doping process on the semiconductor substrate, whereafter a first portion of the semiconductor substrate exhibits a first average doping concentration level and a second portion of the semiconductor substrate exhibits a second average doping concentration level, where there is first difference between the first average doping concentration level and the second average doping concentration level, transferring the substrate to a process chamber of an ion implantation system, and performing a non-uniform ion implantation process on the semiconductor substrate to create a second difference between the first average doping concentration level and the second average doping concentration level, where the second difference is less than the first difference.