In accordance with the present invention there is provided a nanoparticle, comprising—a core, —an outer layer, and —a buffer layer located between said core and said outer layer, wherein the buffer layer prevents energy transfer between the core and the outer layer. In another aspect of the invention there is provided a nanoparticle as described herein for use in therapy, a nanoparticle according as described herein for use in treatment of a tumor, and a nanoparticle as used herein for use in in vivo imaging According to another aspect of the invention there is provided a method for the production of a nanoparticle as described herein, comprising the steps of—heating of a solution comprising core precursors, followed by—injection of a dispersion comprising buffer layer precursors, followed by—injection of a dispersion comprising outer layer precursors. Another aspect of the invention is a method for in vivo imaging or treatment or both of a human or animal, comprising the steps of: —administering nanoparticles as described herein to a patient, —irradiating at least part of the patient's body with one or more types of radiation. According to yet another aspect of the invention there is provided the use of a nanoparticle as described herein for therapy, in vivo imaging, or both.

An efficient green method for the synthesis of noble metal/transition metal oxide nanocomposite comprising reducing noble metal salt and a templating metal oxide is disclosed. The method is a one-step method comprises mixing coffee seed husk extract, a noble metal precursor, and a transition metal precursor; and filtering and drying the nanocomposite. The nanocomposite prepared by the method of the invention displays all the characteristics and biocidal activity of a composite prepared by traditional methods.

A nuclear fuel element for use in a nuclear reactor may include a plurality of metal fuel sheaths extending along a longitudinal fuel element axis and spaced apart from each other, the plurality of fuel sheaths comprising a first fuel sheath having an inner surface, an opposing outer surface and a hollow interior configured to receive nuclear fuel material. A carbon coating may be on the inner surface of the first fuel sheath. The carbon coating may include more than 99.0% wt of a carbon material including more than 20% wt of carbon nanotubes and less than about 0.01% wt of organic contaminants.

Provided are an atomic layer sheet that contains boron and oxygen as framework elements, is networked by nonequilibrium couplings having boron-boron bonds, and has a molar ratio of oxygen to boron (oxygen/boron) of less than 1.5, a laminated sheet containing a plurality of such atomic layer sheets and metal ions between ones of the sheets, and a thermotropic liquid crystal and a lyotropic liquid crystal containing these. In addition, there is provided a method for manufacturing an atomic layer sheet and/or a laminated sheet containing boron and oxygen, the method including: adding MBH.sub.4, where M represents an alkali metal ion, into a solvent containing an organic solvent in an inert gas atmosphere to prepare a solution; and exposing the solution to an atmosphere containing oxygen.

To provide Cd-free chalcopyrite-based quantum dots with a narrow fluorescence FWHM and a high fluorescence quantum yield. The quantum dots of the present invention contain AgIn.sub.xGa.sub.1-xS.sub.ySe.sub.1-y or ZnAgIn.sub.xGa.sub.1-xS.sub.ySe.sub.1-y (where 0≤x<1 and 0≤y≤1) and exhibit fluorescence properties including a fluorescence FWHM of less than or equal to 45 nm and a fluorescence quantum yield of greater than or equal to 35% in the green wavelength range to the red wavelength range.

The present disclosure relates to a transition metal chalcogenide for preparing metal nanostructures, metal nanostructures obtained thereby, an electronic instrument including the same, and a method for manufacturing the same. More particularly, the present disclosure relates to a transition metal chalcogenide for preparing metal nanostructures using transition metal dichalcogenide nanosheets as a reducing agent, metal nanostructures obtained thereby, an electronic instrument including the same, and a method for manufacturing the same.

A blended composition containing uncoated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, and/or coated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, which have been coated with at least one layer of a metal oxide, mixtures of at least two metal oxides, metal, metal sulphide, titanium suboxide, titanium oxynitride, FeO(OH), metal alloys and/or rare earth compounds, and their use in various formulations.

The preparation of monodispersed TiO.sub.2 nanocrystals with nanocrystal size between 1-30 nm is described herein. These TiO.sub.2 nanocrystals are used to prepare dispersions into solvents, formulation into monomers, oligomers, and polymers, and nanocomposites from the resulting formulations. Dispersions of nanocrystals can be formed in various solvents at high loading, high transmittance, and low viscosity. Formulations incorporating these nanocrystals and a matrix material are highly stable, where the resulting nanocomposites have high refractive index and are optically transparent in the visible wavelengths, with very little or no scattering.

A black IR reflective or transmissive pigment from which LiDAR responsive black coatings can be formed where the pigment displays a Blackness M.sub.y value similar to non-IR reflective carbon black. The CuO particles display small crystallites of less than 18 nm and an (−111)/(111) reflectance intensity ratio of less than 1.2. A method of forming the CuO particles includes precipitation of CuCO3 or CuCO.sub.3/Cu(OH).sub.2 using an alkali carbonate as a precipitant and calcining the precipitate at about 300° C. to about 400° C.

A system for extracting two dimensional materials from a bulk material by functionalization of the bulk material in a reactor.