A plumbing fixture having a multi-color appearance includes a first portion including a first finish having a first appearance and a second portion including a second portion having a second appearance that differs from the first appearance. The plumbing fixture further includes a transition region between the first portion and the second portion, wherein the appearance of the third region is graduated from the first appearance to the second appearance between a first end of the transition region adjacent the first portion and a second end of the transition region adjacent the second portion. The plumbing fixture has an ombré appearance as a result of the graduated transition between the first portion and the second portion.

A Cu-doped Sb.sub.2Te.sub.3 system phase change material, a phase change memory, and a preparation method thereof belonging to the technical field of micro-nano electronics are provided. A Sb—Te system phase change material is doped with Cu element to form Cu.sub.3Te.sub.2 bonds with both tetrahedral and octahedral structures in the case of local enrichment of Cu. The strongly bonded tetrahedral structure improves the amorphous stability and data retention capability of the Sb—Te system phase change material, and the octahedral structure of the crystal configuration improves the crystallization speed of the Sb—Te system phase change material. A phase change memory including the phase change material and a preparation method of the phase change material are also provided. Through the phase change material provided by the invention, both the speed and amorphous stability of the device are improved, and the comprehensive performance of the phase change memory is also enhanced.

A method includes forming, on a substrate by performing physical vapor deposition in vacuum, an absorber layer including copper (Cu), indium (In), gallium (Ga) and selenium (Se), forming a stack including the substrate and an oxygen-annealed absorber layer by performing in-situ oxygen annealing of the absorber layer to improve quantum efficiency of the image sensor by passivating selenium vacancies due to dangling bonds, and forming a cap layer over the oxygen-annealed absorber layer by performing physical vapor deposition in vacuum. The cap layer includes at least one of: Ga.sub.2O.sub.3.Math.Sn, ZnS, CdS, CdSe, ZnO, ZnSe, ZnIn.sub.2Se.sub.4, CuGaS.sub.2, In.sub.2S.sub.3, MgO, or Zn.sub.0.8Mg.sub.0.2O.

The present disclosure relates to a hydrogen evolution apparatus including an AC power source, a semiconductor electrode and a counter electrode connected to the AC power source, an electrolyte in which the semiconductor electrode is immersed, and a light source which irradiates light on the semiconductor electrode, in which the semiconductor electrode includes a conductive substrate and n-type semiconductor particles dispersed on a p-type semiconductor matrix or p-type semiconductor particles dispersed on an n-type semiconductor matrix which is vertically grown from the conductive substrate.

A Cu-doped Sb.sub.2Te.sub.3 system phase change material, a phase change memory, and a preparation method thereof belonging to the technical field of micro-nano electronics are provided. A Sb—Te system phase change material is doped with Cu element to form Cu.sub.3Te.sub.2 bonds with both tetrahedral and octahedral structures in the case of local enrichment of Cu. The strongly bonded tetrahedral structure improves the amorphous stability and data retention capability of the Sb—Te system phase change material, and the octahedral structure of the crystal configuration improves the crystallization speed of the Sb—Te system phase change material. A phase change memory including the phase change material and a preparation method of the phase change material are also provided. Through the phase change material provided by the invention, both the speed and amorphous stability of the device are improved, and the comprehensive performance of the phase change memory is also enhanced.

A continuous thin film comprises a metal chalcogenide, wherein the metal is selected from the periodic groups 13 or 14 and the chalcogen is: sulphur (S), selenide (Se), or tellurium (Te), and wherein the thin film has a thickness of less than 20 mm. Methods of forming the continuous thin film involve thermally evaporating precursors to form a thin film on the surface of a substrate. In a particular embodiment, molecular beam epitaxy (MBE) is used to grow indium selenide (In2Se3) thin film from two precursors (In2Se3 and Se) and the thin film is used to fabricate a ferroelectric resistive memory device.

Various embodiments may relate to an optical device. The optical device may include a stacked structure having a first surface and a second surface opposite the first surface. The stacked structure may include a plurality of holes or grooves extending from the first surface towards the second surface. The stacked structure may include a transition metal dichalcogenide material (TMDC) material. A thickness of the stacked structure may be of any value less than 100 nm.

Provided is a radio wave transmittable laminate, which includes a substrate; a primer coating layer located on an upper surface of the substrate and including a polymer resin; a metal layer located on an upper surface of the primer coating layer and made of a metal; a plurality of micro cracks formed in the metal layer so as to transmit radio waves; and a hole pattern constituted by a plurality of holes which vertically penetrate the metal layer so as to transmit the radio waves.

A method of forming a material film includes providing a non-photosensitive mask on a substrate to expose a partial region of the substrate, forming a material film on the partial region of the substrate using a sputtering process, removing the non-photosensitive mask, and heat-treating the substrate and the material film from which the non-photosensitive mask is removed under a first gas atmosphere. The material film includes a transition metal and a chalcogen element. The sputtering process may include an RF magnetron sputtering process. The heat treatment may be performed at a higher temperature than a temperature of the forming the material film.

Provided herein are core-shell heterostructures design comprising a metal (e.g., noble metal) nanoparticle core and a transition metal dichalcogenide (TMD) shell, and methods of preparation and use thereof. In particular embodiments, the core-shell heterostructures described herein are synthesized by direct growth of a monolayer or multilayer fullerene-like TMD shell on a metal (e.g., noble metal) nanoparticle core, exhibit unique Raman scattering and photoluminescence characteristics, and are useful, for example, in plasmonic hot electron enhanced optics and optoelectronics.