A method for producing abrasive particles includes: i) providing a starting mixture which contains at least aluminum hydroxide and which can be converted at least into aluminum oxide by a heat treatment, ii) extruding the starting mixture in order to form an extrudate, iii) separating the extrudate into intermediate particles, and iv) heat-treating the intermediate particles. The intermediate particles are converted into abrasive particles which contain aluminum oxide, and the starting mixture is pressed through at least one nozzle element with a plurality of substantially parallel nozzle channels. The nozzle channels are preferably arranged in a mutually spaced manner over the course of the extrusion process, and the extrudate has a spiral or hollow cylindrical shape at least in some sections.

Embodiments of the present invention provide an automatic micro algae culturing device and system for self-cleaning, continual automatic algae culturing and irradiant optimizing. The culturing device includes a photosynthesis tubular reactor for micro algae culturing, with transparent cleaning particles to scrape off any unwanted particles or components such as including and not limited to formation of biofilm. The tubular reactor has multiple double-walled glasses. Inner walls of the tubes in the tubular reactor may be coated with superhydrophobic coating to avoid bio film formation, or sticking of any hydro dirt or dust particles. Because the cleaning particles are transparent, they wont block any sunlight for photosynthesis in the tubular reactor.

Methods of forming dispersible ferroelectric nanoparticles, including polyether-ylated barium titanate nanoparticles. Uses of the dispersible ferroelectric nanoparticles, including as a ferroelectric tracer material, optionally for detecting a presence and/or measuring a distribution of an oil or a hydrocarbon in a subsurface formation and/or flowback fluid. Compositions and methods involving an oil or hydrocarbon recovery fluid and the dispersible ferroelectric nanoparticles for detecting a presence, measuring a distribution, or both of an oil or a hydrocarbon in a subsurface formation and/or flowback fluid.

Doped nanoparticles, methods of making such nanoparticles, and uses of such nanoparticles. The nanoparticles exhibit a metal-insulator phase transition at a temperature of −200° C. to 350° C. The nanoparticles have a broad range of sizes and various morphologies. The nanoparticles can be used in coatings and in device structures.

The present invention is a carbon material for a catalyst carrier of a polymer electrolyte fuel cell, which has a three-dimensional dendritic structure, and simultaneously satisfies the following (A), (B), and (C). (A) By a laser Raman spectroscopic analysis with a wavelength of 532 nm, a standard deviation δ(R) of an intensity ratio (R value) of an intensity of a D-band (near 1360 cm.sup.−1) to an intensity of a G-band (near 1580 cm.sup.−1) measured with a beam diameter of 1 μm at 50 measurement points is from 0.01 to 0.07. (B) A BET specific surface area S.sub.BET is from 400 to 1520 m.sup.2/g. (C) A nitrogen gas adsorption amount V.sub.N:0.4-0.8 during a relative pressure (p/p.sub.0) from 0.4 to 0.8 is from 100 to 300 cc(STP)/g. A method of producing such a carbon material for a catalyst carrier is also included.

Provided is a method for producing a semiconductor nanoparticle including preparing a mixture containing a Ag salt, a salt containing at least one of In and Ga, and an organic solvent; raising the temperature of the mixture to a raised temperature in a range of from 120° C. to 300° C.; and adding a supply source of S to the mixture at the raised temperature in such a manner that a ratio of a number of S atoms to a number of Ag atoms in the mixture increases at a rate of not more than 10/min.

A nanomaterial includes quantum dots having a crystal structure, wherein the quantum dots include an exposed surface in a specific direction, and the exposed surface has a ligand bound thereto.

Self-healing coating compositions are provided. In embodiments, such a composition comprises a liquid medium and a network of hollow capsules extending through the liquid medium in three dimensions, the network comprising a plurality of chains formed from the hollow capsules, aggregates of the hollow capsules, or both, wherein exterior surfaces of the hollow capsules of the plurality of chains define a plurality of channels filled with the liquid medium, and wherein the coating composition has a room temperature viscosity greater than that of the liquid medium. Coated surfaces formed from the compositions and methods of protecting surfaces using the compositions are also provided.

A method embodiment involves preparing single metal or mixed transition metal chalcogenide using exfoliation of two or more different bulk transition metal dichalcogenides in a manner to form an intermediate hetero-layered transition metal chalcogenide structure, which can be treated to provide a single-phase transition metal chalcogenide.

Disclosed are a metal halide perovskite light-emitting material with controlled defects and wavelength converting body having the same, and light-emitting device. Monvalent organic cation (A.sub.2) contained in the perovskite nanocrystal can stabilize the perovskite nanocrystal and suppress the generation of defects in the crystal due to the entropy effect. Remnant A.sub.2 cations not included in the perovskite nanocrystal form a structure surrounding the perovskite nanocrystal particles, and passivate defects generated on the surface of the perovskite nanocrystal particles. Photoluminescence quantum efficiency, photoluminescence lifetime, and stability are improved through passivation of defects, and the metal halide perovskite light-emitting material can be effectively used in a light-emitting layer or a wavelength conversion layer of a light-emitting device.