Exemplary embodiments provide materials and methods of forming high-quality semiconductor devices using lattice-mismatched materials. In one embodiment, a composite film including one or more substantially-single-particle-thick nanoparticle layers can be deposited over a substrate as a nanoscale selective growth mask for epitaxially growing lattice-mismatched materials over the substrate.

A silicon carbide crystal ingot includes first crystal layers and second crystal layers, each being alternately disposed and all containing one of a donor and acceptor, wherein a concentration of the donor or the acceptor that at least one of the second crystal layers has is higher than a concentration of the donor or the acceptor that one of the first crystal layers has, the one of the first crystal layers being in contact with the at least one of the second crystal layers.

A method for the preparation of a cohesive non-porous perovskite layer on a substrate (104) comprising: forming a thin film of a solution containing a perovskite material dissolved in a solvent onto the substrate to form a liquid film (104) of the solution on the substrate, applying a crystallisation agent (112) to a surface of the film to precipitate perovskite crystals from the 5 solution to form the cohesive non-porous perovskite layer (116) on the substrate.

The present invention relates to a multilayer material, comprising a solid substrate coated at least partially with a textured -quartz buffer layer, the crystallographic direction of the -quartz being parallel to the crystallographic direction of the silicon; and on said -quartz buffer layer, a layer of one-dimensional epitaxial ZnO microcrystals (or epitaxial ZnO microwires), said microcrystals being self-assembled. The present invention also relates to a method for producing such a multilayer material, as well as to the industrial use thereof in various technical fields.

A method of producing nanoparticles comprises effecting conversion of a nanoparticle precursor composition to the material of the nanoparticles. The precursor composition comprises a first precursor species containing a first ion to be incorporated into the growing nanoparticles and a separate second precursor species containing a second ion to be incorporated into the growing nanoparticles. The conversion is effected in the presence of a molecular cluster compound under conditions permitting seeding and growth of the nanoparticles.

A method of producing nanoparticles comprises effecting conversion of a molecular cluster compound to the material of the nanoparticles. The molecular cluster compound comprises a first ion and a second ion to be incorporated into the growing nanoparticles. The conversion can be effected in the presence of a second molecular cluster compound comprising a third ion and a fourth ion to be incorporated into the growing nanoparticles, under conditions permitting seeding and growth of the nanoparticles via consumption of a first molecular cluster compound.

Provided is a preparation method for a composite substrate. The preparation method comprises the following steps: (1) growing a crystal layer on one surface of a single-crystal substrate which is used as a seed crystal to obtain a composite crystal layer structure consisting of the single-crystal substrate and the crystal layer; and (2) subjecting the composite crystal layer structure to laser irradiation to form a modified layer inside the single-crystal substrate of the composite crystal layer structure; dividing the single-crystal substrate along the modified layer by applying an external force to obtain a composite substrate. In the preparation method of the present application, by growing a low-quality crystal layer on a high-quality single-crystal substrate and then using a laser cold-cracking cutting process, the composite substrate has high preparation efficiency, good quality, and wide application range.

The present invention provides a facile heteroepitaxial method for growing conductive zinc-catecholate frameworks on bio-fibers with biomimetic connections, which is beneficial to fabricate biocompatible and high-performance photodetectors and chemiresistors, and the corresponding bio-fiber based metal-organic framework. In this method, a conductive layer is first introduced on the surface of polysaccharide bio-fibers, before well-aligned zinc oxide nanoarrays were densely constructed on the bio-fibers by a physiological coagulation mechanism. The obtained fibrous materials may be used in devices, including in electronic components, having the advantages of good stability, environmental-friendly, flame retardancy, and high response.

A method of preparing a core-shell nanorod can include growing a shell of a core-shell nanorod (M1X1)M2X2 in a solution through a slow-injection of M2 precursor solution and X2 precursor solution, wherein the core-shell nanorod includes a M1X1 core.

A method of fabricating an ionic crystal includes providing a single crystal substrate of an ionic crystal material is provided. A patterned mask is applied over the single crystal substrate A growth solution is introduced over the single crystal substrate. The growth solution includes precursors for epitaxial growth of the ionic crystal material on the single crystal substrate such that epitaxial crystals grow over time through pattern openings in the patterned mask into a crystal structure with one or more morphologies.