A method for manufacturing a semiconductor device is provided. The method includes forming at least one epitaxial layer over a substrate; forming a mask over the epitaxial layer; patterning the epitaxial layer into a semiconductor fin; depositing a semiconductor capping layer over the semiconductor fin and the mask, wherein the semiconductor capping layer has a first portion that is amorphous on a sidewall of the mask; performing a thermal treatment such that the first portion of the semiconductor capping layer is converted from amorphous into crystalline; forming an isolation structure around the semiconductor fin; and forming a gate structure over the semiconductor fin.

A semiconductor device has a first substrate made of a first semiconductor material, such as silicon. A sacrificial layer is formed over a first surface of the first substrate. A seed layer is formed over the sacrificial layer. A compliant layer is formed over a second surface of the first substrate opposite the first surface of the first substrate. A first semiconductor layer made of a second semiconductor material, such as silicon carbide, dissimilar from the first semiconductor material is formed over the sacrificial layer. The first substrate and sacrificial layer are removed leaving the first semiconductor layer substantially defect-free. The first semiconductor layer containing the second semiconductor material is formed at a temperature greater than a melting point of the first semiconductor material. A second semiconductor layer is formed over the first semiconductor layer with an electrical component formed in the second semiconductor layer.

A transistor includes a first gate electrode, a first capping layer, a crystalline semiconductor oxide layer, a second capping layer, a first gate dielectric layer, and source/drain contacts. The first capping layer, the crystalline semiconductor oxide layer, and the second capping layer are sequentially disposed over the first gate electrode. Sidewalls of the second capping layer are aligned with sidewalls of the crystalline semiconductor oxide layer. The first gate dielectric layer is located between the first gate electrode and the first capping layer. The source/drain contacts are disposed on the second capping layer. The crystalline semiconductor oxide layer and the source/drain contacts are located on two opposite sides of the second capping layer.

A method includes providing a semiconductor structure having an active region and an isolation structure adjacent to the active region, the active region having source and drain regions sandwiching a channel region for a transistor, the semiconductor structure further having a gate structure over the channel region. The method further includes etching a trench in one of the source and drain regions, wherein the trench exposes a portion of a sidewall of the isolation structure, epitaxially growing a first semiconductor layer in the trench, epitaxially growing a second semiconductor layer over the first semiconductor layer, changing a crystalline facet orientation of a portion of a top surface of the second semiconductor layer by an etching process, and epitaxially growing a third semiconductor layer over the second semiconductor layer after the changing of the crystalline facet orientation.

Provided are a graphene interconnect structure, an electronic device including the graphene interconnect structure, and a method of manufacturing the graphene interconnect structure. The graphene interconnect structure may include: a first oxide dielectric material layer; a second oxide dielectric material layer on a surface of the first oxide dielectric material layer and having a dielectric constant greater than that of the first oxide dielectric material layer; and a graphene layer on a surface of the second oxide dielectric material layer opposite to the surface on which the first oxide dielectric material layer is located.

An InN nanorod epitaxial wafer grown on an aluminum foil substrate (1) sequentially comprises the aluminum foil substrate (1), an amorphous aluminum oxide layer (2), an AlN layer (3) and an InN nanorod layer, (4) from bottom to top. The wafer can be prepared by pretreating the aluminum foil substrate with an oxidized surface and carrying out an in-situ annealing treatment; then, in a molecular beam epitaxial growth process, forming AlN nucleation sites on the annealed aluminum foil substrate, nucleating on the AlN and growing InN nanorods on the AlN, where the substrate temperature is 400-700° C., the pressure of a reaction chamber is 4.0-10.0×10.sup.−5 Torr and the beam ratio of V/III is 20-40.

Embodiments of the present application provide a semiconductor structure and a manufacturing method therefor. A buffer layer is disposed on a substrate layer, and the buffer layer includes a first buffer layer and a second buffer layer. By doping a transition metal in the first buffer layer, a deep level trap may be formed to capture background electrons, and diffusion of free electrons toward the substrate may also be avoided. By decreasing a doping concentration of the transition metal in the second buffer layer, a tailing effect is avoided and current collapse is prevented. By doping periodically the impurity in the buffer layer, the impurity may be as an acceptor impurity to compensate the background electrons, and then a concentration of the background electrons is reduced. By using the periodic doping method, dislocations, caused by doping, in the buffer layer may be effectively reduced.

The present invention provides a nitride semiconductor substrate suitable for a high frequency device. The nitride semiconductor substrate has a substrate, a buffer layer made of group 13 nitride semiconductors, and an active layer made of group 13 nitride semiconductors in this order, wherein the substrate is composed of a first substrate made of polycrystalline aluminum nitride, and a second substrate made of Si single crystal having a specific resistance of 100 Ω.Math.cm or more, formed on the first substrate, the average particle size of AlN constituting the first substrate is 3 to 9 μm, and preferably, the second substrate grown by the MCZ method has an oxygen concentration of 1E+18 to 9E+18 atoms/cm.sup.3 and a specific resistance of 100 to 1000 Ω.Math.cm.

A method includes forming a semiconductor structure. The structure includes a first material, a blocking material, a second material in an amorphous form, and a third material in an amorphous form. The blocking material is disposed between the first material and the second material. At least the second material and the third material each comprise silicon and/or germanium. The structure is exposed to a temperature above a crystallization temperature of the third material and below a crystallization temperature of the second material. Semiconductor structures, memory devices, and systems are also disclosed.

Gate-all-around integrated circuit structures having germanium nanowire channel structures, and methods of fabricating gate-all-around integrated circuit structures having germanium nanowire channel structures, are described. For example, an integrated circuit structure includes a vertical arrangement of horizontal nanowires above a fin, each of the nanowires including germanium, and the fin including a defect modification layer on a first semiconductor layer, a second semiconductor layer on the defect modification layer, and a third semiconductor layer on the second semiconductor layer. A gate stack is around the vertical arrangement of horizontal nanowires. A first epitaxial source or drain structure is at a first end of the vertical arrangement of horizontal nanowires, and a second epitaxial source or drain structure is at a second end of the vertical arrangement of horizontal nanowires.