The present invention is directed to adjustable chromophore compounds and materials (e.g., ophthalmic lens materials) incorporating those compounds. The adjustable chromophore compounds include a chemical moiety that structurally changes upon exposure to predetermined electromagnetic radiation (e.g., two photon radiation) as well as lens materials, particularly intraocular lens materials that incorporate those compounds.

The invention relates to an apparatus and methods for producing liquid colloids such as suspensions of nanoparticles, in which liquid feedstock materials are reacted on a reaction surface of a rotatable plate. The apparatus has a first plate (101) mounted for rotation about a rotation axis (102), the first plate (101) providing a reaction surface (103) having a concave portion; first (106) and second (107) inlet lines arranged to introduce respective first and second liquid feedstock materials to the reaction surface (103); and a collection unit (110) arranged to collect a reaction product formed from reaction of the liquid feedstock materials as a liquid colloid ejected from an outer edge of the plate (101).

A method for reducing carbon dioxide is provided. In the present method, used is an anode electrode comprises a stacked structure of a photoelectric conversion layer, a metal layer, and an In.sub.xGa.sub.1-xN layer (where 0<x1). The In.sub.xGa.sub.1-xN layer is of i-type or n-type. The metal layer is interposed between the photoelectric conversion layer and the In.sub.xGa.sub.1-xN layer. When irradiating the anode electrode with light, a first light part included in the light is absorbed by the In.sub.xGa.sub.1-xN layer and a second light part included in the light travels through the In.sub.xGa.sub.1-xN layer. The second light part is absorbed by the photoelectric conversion layer to generate electric power in the photoelectric conversion layer. The second light part has a longer wavelength than the first light part. The carbon dioxide contained in the first electrolyte solution is reduced on the cathode electrode.

The invention provides a photoreactor assembly (1000) comprising a reactor (200) and a light source arrangement (1010): wherein: the light source arrangement (1010) comprises a plurality of light sources (10) configured to generate light source radiation (11) selected from one or more of UV radiation, visible radiation, and IR radiation, wherein each light source (10) comprises a light emitting surface (12): the reactor (200) is configured for hosting a fluid (5) to be treated with the light source radiation (11), wherein the reactor (200) comprises one or more reactor walls (210), wherein at least one of the one or more reactor walls (210) defines wall cavities (220) and is configured in a radiation receiving relationship with the plurality of light sources (10); wherein the at least one of the one or more reactor walls (210) is transmissive for the light source radiation (11); wherein one or more of the light sources (10) are at least partly configured in the wall cavities (220) whereby the light emitting surfaces (12) are within the wall cavities (220) and the at least one of the one or more reactor walls (210) at least partly encloses the light emitting surfaces (12).

A device includes an insulated reaction chamber, light sources above a stirring module, the light sources surrounding the reaction chamber, and holders containing reaction vessels, the holders configured to fit within the insulated reaction chamber in a manner that enables an even distribution of light between the reaction vessels.

A reactor cell assembly having an annular volume, a top endcap fitting having a reactant gas inlet, a bottom compression endcap fitting having a product gas outlet, a photocatalyst packed bed positioned in the annular volume, a porous base filter to position the photocatalyst packed bed in the annular volume, and a light housing. At least one of an outer portion and an inner portion of the light housing comprises a circumferential array of photon emitters arranged to uniformly emit photons incident on the photocatalyst packed bed to activate continuous photo-induced gas-phase reactions as at least one gaseous reactant introduced via the gas inlet flows through the photocatalyst packed bed and at least one resultant gaseous product exits via the gas outlet.

A fluid treatment system for treating a fluid with ultraviolet light. The system includes a detachable light source assembly having a thermally conductive outer wall, an inner wall disposed inside the outer wall and surrounding an inner space within the inner wall that defines a treatment zone, and an ultraviolet light source disposed between the outer wall and the inner wall and configured to emit ultraviolet light toward the treatment zone, and a reactor vessel having an inlet port for receiving a fluid and an outlet port for expelling treated fluid, the reactor vessel configured to receive the light source assembly in an attached state such that a space between a wall of the reactor vessel and the outer wall of the light source assembly defines a cooling zone in which the outer wall is cooled by contacting the fluid.

A multicomponent photocatalyst includes a reactive component optically, electronically, or thermally coupled to a plasmonic material. A method of performing a catalytic reaction includes loading a multicomponent photocatalyst including a reactive component optically, electronically, or thermally coupled to a plasmonic material into a reaction chamber; introducing molecular reactants into the reaction chamber; and illuminating the reaction chamber with a light source.

The present disclosure relates to a process for chlorination of a polymer. The process of the present disclosure includes minimum use of light and maximum chlorine utilization for getting maximum chlorination yield. The chlorinated polymer obtained by the process of the present disclosure exhibit improved properties viz. thermal stability, color, inherent viscosity and mechanical properties.

A method of forming three-dimensional shaped microparticles in a microfluidic device includes flowing a mixture of a monomer and photoinitiator in a microfluidic channel having a plurality of pillars disposed therein to define a flow stream having a pre-defined shape and temporarily stopping the same. One or more portions of the flow stream are polymerized by passing polymerizing light through one or more masks and onto the flow stream, the polymerization process forming a plurality of three-dimensional shaped microparticles. The three-dimensional shape of the microparticle may be geometrically complex by using non-rectangular 2D orthogonal shapes for the flow and/or masked light source. The microparticles may include protected regions on which cells can be adhered to and protected from shear forces. The flow stream is restarted to flush out the newly formed microparticles and prepare the device for the next cycle of particle formation.