The invention relates to processes for the extraction of products from titanium-bearing materials or a composition produced in a process for the production of titanium dioxide, and more particularly, although not exclusively, extracting titanium dioxide and/or one or more other products from iron making slag.

An inorganic metal halide compound for one of a light emitting device and an optical member, the compound being represented by Formula 1 and having a double perovskite structure of Formula 1 as defined herein.

The present invention provides a two-dimensional double perovskite nanomaterial represented by the formula Cs.sub.2ABX.sub.6 or L.sub.4[Cs.sub.2ABX.sub.6].sub.n-1ABX.sub.8, wherein A is a metal ion selected from Ag(I), Au(I), and Cu(I); B is a metal ion selected from In(III), Bi(III), Sb(III), Fe(III), and Tl(III); X is a halogen; L is a ligand; and n represents the number of metal-halide octahedral layers present in said nanomaterial. The invention further provides a light emitting material and electronic-, optic-, or optoelectronic device comprising said nanomaterial; as well as methods for the preparation of said nanomaterial.

A method for depositing an inorganic perovskite layer, comprising the following steps: providing a substrate and an inorganic target; positioning the substrate and the target in a close-space sublimation furnace; depositing an inorganic perovskite layer onto the substrate by sublimation of the target.

The present invention aims to obtain a resin composition with low thermal expansion property by suppressing functional deterioration in negative thermal expansion property when a negative thermal expansion material is added to a thermoplastic resin and heat-processed. The present invention provides a resin composition including metal oxide particles and a thermoplastic resin, both having a negative thermal expansion property. The negative thermal expansion of the particles is attributed to a crystal phase transition, which is driven by electron transfer between the constituent metals, and a covalent protective layer that inhibits the electron transfer is formed between the particles and the thermoplastic resin.

A method for producing a solid composition according to the present disclosure is a method for producing a solid composition that is used for forming a functional ceramic having a first crystal phase. The method for producing a solid composition includes: producing an oxide composed of a second crystal phase different from the first crystal phase; and mixing the oxide and an oxo acid compound.

There are provided a piezoelectric laminate, which include, on a substrate in the following order, a lower electrode layer and a piezoelectric film, in which the piezoelectric film contains a perovskite-type oxide, the piezoelectric film includes a first region in which the perovskite-type oxide contains, as a main component, a first perovskite crystal in which a first angle formed by a (100) plane orientation or a (001) plane orientation and a normal direction of a surface of the substrate is 5°˜30°, and includes a second region provided between the first region and the lower electrode layer, in which the perovskite-type oxide contains, as a main component, a second perovskite crystal in which a second angle formed by the (100) plane orientation or the (001) plane orientation and the normal direction is less than 5°, and a thickness of the second region is 30 nm or more.

An A/M/X crystalline material, a photovoltaic device, and preparation methods thereof are provided. The photovoltaic device includes a photoactive crystalline material layer. The photoactive crystalline material layer includes a penetrating crystal, where the penetrating crystal is a crystal penetrating through the photoactive crystalline material layer, and a percentage p of a quantity of penetrating crystals in a total quantity of crystals of the photoactive crystalline material layer is ≥80%. The photoactive crystalline material layer includes a backlight side and a backlight crystal, where the backlight crystal is a crystal exposed to the backlight side and has a backlight crystal face exposed to the backlight side. At least one region of the backlight side has an average flatness index R.sub.avg being ≤75.

A cathode configured to use oxygen as a cathode active material includes: a porous film including a metal oxide, where a porosity of the porous film is about 50 volume percent to about 95 volume percent, based on a total volume of the porous film, and an amount of an organic component in the porous film is 0 to about 2 weight percent, based on a total weight of the porous film.

A dielectric composition includes dielectric particles. At least one of the dielectric particles include a main phase and a secondary phase. The main phase has a main component of barium titanate. The secondary phase exists inside the main phase and has a higher barium content than the main phase.