Apparatuses and methods are provided for applying radio frequency (RF) energy from a source of electromagnetic energy to an object in an energy application zone. At least one processor may be configured to acquire information indicative of electromagnetic energy loss associated with at least a portion of the energy application zone. The processor may be further configured to determine a weight to be applied to each of a plurality of electromagnetic field patterns each having a known electromagnetic field intensity distribution and cause the source to supply each of the plurality of electromagnetic field patterns to the energy application zone at the determined weights.

Compositions including one or more polymers are provided. Exemplary polymers include polymeric carbon monoxides. The compositions can be prepared by subjecting a source material to x-rays, optionally at increased pressures. The compositions can be used in a variety of applications, such as fuels, optics, and electronics.

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.

Apparatus for facilitating a chemical reaction through the application of light, including a light source providing illumination at a selected wavelength, a lens material adapted to be in physical contact with the light source, when in use, and a receptacle for holding a reaction vial in which the chemical reaction takes place, the receptacle adapted to position a portion of the reaction vial in physical contact with the lens material when in use, wherein the lens material has a refractive index that facilitates the transmission of the illumination from the light source to the reaction vial. Alternatively, the receptacle and vial may be replaced by a reaction plate in which reaction wells are formed.

Disclosed is a method of irradiating a composition having water and hydrogen-terminated nanodiamonds with light that generates water-solvated electrons from the nanodiamonds. The method can be used to degrade fluoroalkyl compounds such as perfluorooctane sulfonate.

Methods, systems, and apparatuses for producing one or more of photon enhanced oxidizing agents, trioxygen, hydrogen and its ions, oxygen and its ions, ROS and electronically modified oxygen derivatives from oxidizing agents that are exposed to photon emissions at a wavelength in a range of 0.01 nm to 845 nm, wherein wavelengths that photo-dissociate trioxygen may be excluded. The methods, systems and apparatuses enhance the effectiveness of photo-oxidation, photocatalytic, and/or photochemical reactions or a combination of these reactions.

Described herein are systems incorporating a Casimir cavity, such as an optical Casimir cavity or a plasmon Casimir cavity. The Casimir cavity modifies the zero-point energy density therein as compared to outside of the Casimir cavity. The Casimir cavities are paired in the disclosed systems with product generating devices and the difference in zero-point energy densities is used to directly drive the generation of products, such as chemical reaction products or emitted light.

An apparatus for the production of hydrogen peroxide. The apparatus can have a substrate consisting of a substantially triboelectrically neutral material, a catalyst disposed upon the substrate, and an energy source to provide energy for ambient oxygen and water vapor to react and form hydrogen peroxide. The apparatus does not produce any ozone as a byproduct. The apparatus produces pure hydrogen peroxide gas which is not insulated by water molecules. Further the hydrogen peroxide gas, due to the fact that it is uninsulated by water molecules, is self-regulating to a concentration of 0.03 parts per million even when continuously produced by the apparatus.

According to one embodiment, a photochemical reaction system comprises a CO.sub.2 production unit, a CO.sub.2 absorption unit, and a CO.sub.2 reduction unit. The CO.sub.2 reduction unit comprises a laminated body and an ion transfer pathway. The laminated body comprises an oxidation catalyst layer producing O.sub.2 and H.sup.+ by oxidizing H.sub.2O, a reduction catalyst layer producing carbon compounds by reducing CO.sub.2 absorbed by the CO.sub.2 absorption unit, and a semiconductor layer formed between the oxidation catalyst layer and the reduction catalyst layer and develops charge separation with light energy. The ion transfer pathways make ions move between the oxidation catalyst layer side and the reduction catalyst layer side.

We disclose herein a method of annealing a composition to produce a film for a sensing device, the composition comprising at least one metal oxide material, the method comprising: depositing the composition on one side of a substrate; providing a source of electromagnetic radiation in a proximity to the composition; exposing a surface of the composition to a first dose of electromagnetic radiation, wherein the first dose comprises a first property which induces annealing of the composition; exposing the surface of the composition to a second dose of electromagnetic radiation, wherein the second dose comprises a second property which induces annealing of the composition, wherein the first property is substantially the same or different to the second property.