A method includes exposing a non-aqueous solution to ultraviolet illumination, where the non-aqueous solution includes one or more lanthanide elements and one or more photo-initiators. The method also includes producing lanthanide nanoparticles using the non-aqueous solution. The non-aqueous solution could be formed by mixing a first non-aqueous solution including the one or more lanthanide elements and a second non-aqueous solution including the one or more photo-initiators. The non-aqueous solution could include one or more metallic salts, where each metallic salt includes at least one lanthanide element. The one or more metallic salts could include erbium chloride, and the one or more photo-initiators could include benzophenone. The non-aqueous solution could include an organic solvent, such as an alcohol.

A method of forming birnessite -MnO.sub.2 nanosheets is provided. The method includes oxidizing manganese (Mn.sup.2+) in the presence of a source of nitrate and a light source.

A hydrogen generating fuel cell includes an anode and a cathode separated by a channel configured to hold liquid water or water vapor. At least one of the anode and the cathode are porous. The hydrogen generating fuel cell includes a power source electrically connected to the anode and the cathode and an ultraviolet radiation source positioned to emit ultraviolet radiation from the anode to the cathode, the cathode to the anode, or both directions. A hydrogen generating system and a method of generating hydrogen are also disclosed.

Methods for forming melt processable, actinic radiation polymerizable and crosslinkable adhesives are described. In certain versions, the adhesives or pre-adhesive compositions include two initiators and are polymerized and/or crosslinked by exposure to actinic radiation such as UV light or electron beam radiation. Also described are pre-adhesive compositions including polymerizable monomers, articles including the adhesives, and various methods and systems related to the adhesives and their application. In addition, various apparatuses are described for polymerizing or crosslinking the compositions.

This disclosure provides a method for quantum dots ligand exchanges and an apparatus of the same. The method includes providing a first ligand modified quantum dot, a second ligand and a first polymer. The method includes mixing the first ligand modified quantum dot, the second ligand and the first polymer in a solvent to perform the first ligand exchange, so as to obtain a second modified quantum dot. The first polymer contains a first functional group, which can have a first reaction with the first ligand, but do not react with the second ligand under the same conditions.

Methods for reducing the color of phospholipid compositions comprising lecithin are disclosed. The phospholipid composition is exposed to ultraviolet light to reduce the color of the composition. The phospholipid composition may be diluted and/or heated prior to exposure to ultraviolet light to improve the flow properties of the composition. The phospholipid composition may be cooled and/or concentrated after color reduction.

The present disclosure relates to a UV- and visible-light photocatalytic titanium dioxide composite material. In particular, the disclosure relates to a 5 photocatalytic titanium oxide composite material for the decomposition of airborne pollutants.

The invention consists of an assembly of a light (e.g., UV, visible, IR) source, a reaction vial holder and a photochemistry device that allows for conducting arrays of photochemical reaction conditions at room temperature with magnetic stirring. The photochemistry assembly is compatible with multiple reaction vial size holder.

A method of removing at least one single ring aromatic hydrocarbon from a hydrocarbon contaminated fluid. The method includes contacting the hydrocarbon contaminated fluid with carbon nanotubes to adsorb the at least one single ring aromatic hydrocarbon while exposing the hydrocarbon contaminated fluid and the carbon nanotubes to UV irradiation from at least one UV light source, preferably a UV light emitting diode (LED), with a wavelength of about 315-415 nm, preferably about 365 nm, to form a treated fluid having a reduced concentration of the at least one single ring aromatic hydrocarbon relative to the hydrocarbon contaminated fluid.

A fluid processing apparatus includes: a casing having a fluid inlet pipe and a fluid outlet pipe; multiple rectifying plates with holes in parallel with each other provided within the casing on a side of the fluid inlet pipe, the rectifying plates being perpendicular to a longitudinal axis of the casing; and a light source for irradiating fluid passing from the fluid inlet pipe through the casing to the fluid outlet pipe with ultraviolet rays.