Provided is an epitaxial wafer having an excellent gettering capability and a suppressed formation of epitaxial defects. The epitaxial wafer has a specified resistivity, and includes a modifying layer formed on a surface portion of the silicon wafer and composed of a predetermined element including at least carbon, in the form of a solid solution in the silicon wafer; and an epitaxial layer having a resistivity that is higher than the resistivity of the silicon wafer, wherein a concentration profile of the predetermined element in the modifying layer in a depth direction thereof meets a specified full width half maximum and a specified peak concentration.

Provided is a semiconductor epitaxial wafer having metal contamination reduced by achieving higher gettering capability, a method of producing the semiconductor epitaxial wafer, and a method of producing a solid-state image sensing device using the semiconductor epitaxial wafer. The method of producing a semiconductor epitaxial wafer 100 includes a first step of irradiating a semiconductor wafer 10 containing at least one of carbon and nitrogen with cluster ions 16 thereby forming a modifying layer 18 formed from a constituent element of the cluster ions 16 contained as a solid solution, in a surface portion of the semiconductor wafer 10; and a second step of forming a first epitaxial layer 20 on the modifying layer 18 of the semiconductor wafer 10.

A method is disclosed of removing a first material disposed over a second material adjacent to a field effect transistor gate having a gate sidewall layer that comprises an etch-resistant material on a gate sidewall. The method includes subjecting the first material to a gas cluster ion beam etch process to remove first material adjacent to the gate, and detecting exposure of the second material during the gas cluster ion beam (GCIB) etch process.

Methods for doping a sub-fin region of a semiconductor structure include providing a semiconductor structure that comprises a substrate and a plurality of fins formed on the substrate, the plurality of fins having sub-fin regions adjacent to the substrate; removing the substrate to expose a portion of the sub-fin regions of the plurality of fins, and implanting a dopant material into the exposed portion of the sub-fin region. The method may also include performing an annealing process after the implantation such that the dopant becomes electrically active. The method may also include patterning the backside of the semiconductor structure. Devices constructed using the disclosed methods are also provided, and other embodiments are discussed.

A method for shallow etching a substrate surface forms a shallow modified substrate layer overlying unmodified substrate using an accelerated neutral beam and etches the modified layer, stopping at the unmodified substrate beneath, producing controlled shallow etched substrate surfaces.

Provided is a method of manufacturing an epitaxial wafer having an excellent gettering capability while suppressing formation of epitaxial defects. The method includes: a cluster ion irradiation step of irradiating a surface of a silicon wafer having a resistivity of from 0.001 .Math.cm to 0.1 .Math.cm with cluster ions containing at least carbon at a dose of from 2.010.sup.14/cm.sup.2 to 1.010.sup.16/cm.sup.2 to form, on a surface portion of the silicon wafer, a modifying layer composed of a constituent element of the cluster ions in the form of a solid solution; and an epitaxial layer forming step of forming, on the modifying layer on the silicon wafer, an epitaxial layer having a resistivity that is higher than the resistivity of the silicon wafer.

A method of making a nanowire device includes disposing a first nanowire stack over a substrate, the first nanowire stack including alternating layers of a first and second semiconducting material, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; disposing a second nanowire stack over the substrate, the second nanowire stack including alternating layers of the first and second semiconducting materials, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; forming a first gate spacer along a sidewall of a first gate region on the first nanowire stack and a second gate spacer along a sidewall of a second gate region on the second nanowire stack; oxidizing a portion of the first nanowire stack within the first gate spacer; and removing the first semiconducting material from the first nanowire stack and the second nanowire stack.

A method of forming a variable spacer in a vertical transistor device includes forming a first source/drain of a first transistor on a substrate; forming a second source/drain of a second transistor on the substrate adjacent to the first source/drain, an isolation region arranged in the substrate between the first source/drain and the second source/drain; depositing a spacer material on the first source/drain; depositing the spacer material on the second source/drain; forming a first channel extending from the first source drain and through the spacer material; forming a second channel extending from the second source/drain and through the spacer material; wherein the spacer material on the first source/drain forms a first spacer and the spacer material on the second source/drain forms a second spacer, the first spacer being different in thickness than the second spacer.

A method of making a nanowire device includes disposing a first nanowire stack over a substrate, the first nanowire stack including alternating layers of a first and second semiconducting material, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; disposing a second nanowire stack over the substrate, the second nanowire stack including alternating layers of the first and second semiconducting materials, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; forming a first gate spacer along a sidewall of a first gate region on the first nanowire stack and a second gate spacer along a sidewall of a second gate region on the second nanowire stack; oxidizing a portion of the first nanowire stack within the first gate spacer; and removing the first semiconducting material from the first nanowire stack and the second nanowire stack.

A method includes forming a dielectric layer on a substrate and patterning the dielectric layer to form an opening in the dielectric layer. A first layer of metallic material (e.g., non-nitride metal) is deposited to form a liner layer on an upper surface of the dielectric layer and on exposed surfaces within the opening. A second layer of metallic material (e.g., copper) is deposited to fill the opening with metallic material. An overburden portion of the second layer of metallic material is removed by planarizing the second layer of metallic material down an overburden portion of the liner layer on the upper surface of the dielectric layer. A surface treatment process (e.g., plasma nitridation) is performed to convert the overburden portion of the liner layer into a layer of metal nitride material. The layer of metal nitride material is selectively etched away using a wet etch process.