The invention provides an element comprising: an electrical component, an optical medium comprising medium material comprising a silicone transmissive for one or more of UV radiation and visible radiation, wherein the electrical component is embedded in the optical medium, an electrical connector for functionally coupling the electrical component external to the optical medium, wherein the electrical connector is embedded in the optical medium over at least part of its length; and a water barrier at least partly embedded in the optical medium and configured to enclose at least part of the electrical connector.

One aspect described herein is a fluid treatment apparatus. The apparatus may comprise a body extending along a flow path between a first end and a second end opposite of the first end along the flow path, the first end comprising an inlet along the flow path, the second end comprising an outlet along the flow path; a flow channel extending inside the body along the flow path to direct a fluid from the inlet to the outlet; and a solid-state radiation source mountable in a cavity of the flow channel to emit radiation into the flow channel along the flow path, the solid-state radiation source comprising a thermally conductive portion positioned to be contacted by the fluid when the fluid is flowing from the inlet to the outlet and the solid-state radiation source is mounted in the cavity. Related apparatus, devices, and methods also are described.

A system capable of a germicidal treatment of highly opaque liquids, featuring a filter, which prevents wavelengths above the UV-C spectrum reaching the liquid being treated, one or more spiral-shaped tubes extending from an inlet end to an outlet end creating a fluidic pathway, and one or more light sources illuminating the one or more spiral-shaped tubes, wherein the one or more light sources emit light in a wavelength range between 180-300 nm.

A process includes converting dioxygen in oxygen nanobubbles to ozone by exposure of the dioxygen to UV light in a UV reactor.

A method of making a multicomponent photocatalyst, includes inducing precipitation from a pre-cursor solution comprising a pre-cursor of a plasmonic material and a pre-cursor of a reactive component to form co-precipitated particles; collecting the co-precipitated particles; and annealing the co-precipitated particles to form the multicomponent photocatalyst comprising a reactive component optically, thermally, or electronically coupled to a plasmonic material.

Provided herein are methods of CO.sub.2 reduction to methanol or CO using a Cu.sub.2O catalyst.

Methods and systems to decarbonize natural gas using sulfur to produce hydrogen and polymers are provided. Sulfur can be introduced in elemental form or as hydrogen sulfide, as may be desired. Decarbonization of natural gas involves introducing natural gas and H.sub.2S to a first reactor to produce first reactor products including CS.sub.2 and H.sub.2. The CS.sub.2 can subsequently be polymerized and the H.sub.2 recovered in a purified form with little or no carbon emissions.

The invention provides a layer stack (500) comprising a first silicone layer (510), wherein the first silicone layer (510) has a first surface (511) and a second surface (512), wherein the first silicone layer (510) is transmissive for UV radiation having one or more wavelengths selected from the range of 200-380 nm, wherein the layer stack (500) further comprises one or more of:a first layer element configured at a first side of the first surface (511), wherein the first layer element is associated by a chemical binding with the first surface (511) directly or via a first intermediate layer, which is transmissive for UV radiation having one or more wavelengths selected from the range of 200-380 nm, wherein the first layer element at least comprises a first layer differing in composition from the first silicone layer (510), and wherein the first layer element is transmissive for UV radiation having one or more wavelengths selected from the range of 200-380 nm; and a second layer element (620) configured at a second side of the second surface (512) wherein the second layer element (620) is associated by a chemical binding with the second surface (512) directly or via a second intermediate layer, wherein the second layer element (620) at least comprises a second layer (1220) differing in composition from the first silicone layer (510).

A light irradiation device includes a protective tube, which has a wire insertion path therein, a light source unit facing and disposed along an upper part of the protective tube, and a gutter-shaped concave reflection mirror facing the light source unit and provided below the protective tube. The concave reflection mirror is received in a gutter-shaped concave accommodating part provided in a holding body, and has flange portions extending from the outer surface in the horizontal direction. The convex reflection mirror is detachably affixed to the holding body with the flange portions.

A stirring device, in particular reactor stirring device, has at least one holder which is configured for holding at least one brittle unit within a container relative to at least one container wall of the container, and which has at least one holding unit for this purpose. At least one holding position of the holder relative to the container wall can be adapted by means of the holding unit.