A method of electrochemical synthesis, and specifically relates to a green production process for an iodate. The process includes preparing lithium iodate by means of an electrolysis method, and then reacting the prepared lithium iodate with an iodide to prepare the iodate. In the process, a mother liquor is recycled, no effluent waste is produced, a product yield is high, and the generation of a large amount of waste salt is avoided. The process is green and environmentally friendly. During the synthesis process of preparing lithium iodate by means of an electrolysis method, using a clean electrolysis process does not require the addition of an oxidant and other additional original auxiliary materials as required by a chemical method, the original auxiliary materials are simple, and a produced iodate product has a high quality.

A method of electrochemical synthesis, and specifically relates to a green production process for an iodate. The process includes preparing lithium iodate by means of an electrolysis method, and then reacting the prepared lithium iodate with an iodide to prepare the iodate. In the process, a mother liquor is recycled, no effluent waste is produced, a product yield is high, and the generation of a large amount of waste salt is avoided. The process is green and environmentally friendly. During the synthesis process of preparing lithium iodate by means of an electrolysis method, using a clean electrolysis process does not require the addition of an oxidant and other additional original auxiliary materials as required by a chemical method, the original auxiliary materials are simple, and a produced iodate product has a high quality.

Provided are products of manufacture and methods for the removal of gaseous methane and carbon dioxide, for example, for the removal of environmental or atmospheric or anthropogenically produced gaseous methane and carbon dioxide. Products of manufacture as provided herein comprise living emission abolish filters (LEAFs) for the removal of methane and carbon dioxide, where the “living” component of the “emission abolish filter”, or biofilter, comprises a methane-capturing bioagent, optionally comprising halophilic methanotroph bacterium. Products of manufacture as provided herein are manufactured as arrays, sheets, microfibers and/or microbeads comprising immobilized living, active methane-capturing bioagents, optionally comprising halophilic methanotroph bacterium. In alternative embodiments, the methane-capturing bioagents are enclosed or immobilized in or onto a crystal gel matrix or a nanoshell. Products of manufacture as provided herein can replace gas flares, flare stacks or a gas combustion devices, or are used with a methane scrubbing system.

Provided are products of manufacture and methods for the removal of gaseous methane and carbon dioxide, for example, for the removal of environmental or atmospheric or anthropogenically produced gaseous methane and carbon dioxide. Products of manufacture as provided herein comprise living emission abolish filters (LEAFs) for the removal of methane and carbon dioxide, where the “living” component of the “emission abolish filter”, or biofilter, comprises a methane-capturing bioagent, optionally comprising halophilic methanotroph bacterium. Products of manufacture as provided herein are manufactured as arrays, sheets, microfibers and/or microbeads comprising immobilized living, active methane-capturing bioagents, optionally comprising halophilic methanotroph bacterium. In alternative embodiments, the methane-capturing bioagents are enclosed or immobilized in or onto a crystal gel matrix or a nanoshell. Products of manufacture as provided herein can replace gas flares, flare stacks or a gas combustion devices, or are used with a methane scrubbing system.

An electrochemical method includes performing anodic halogenation of Cu foils, performing subsequent oxide-formation in a KHCO.sub.3 electrolyte, and performing an electroreduction in neutral KHCO.sub.3 to generate a copper catalyst.

There is provided an anode for electrolytic synthesis capable of electrolytically synthesizing fluorine gas or a fluorine containing compound by a simple process and at a low cost while suppressing the occurrence of an anode effect. An anode for electrolytic synthesis (3) for electrolytically synthesizing fluorine gas or a fluorine containing compound includes an anode substrate formed of a carbonaceous material and a metal coating film coating the anode substrate. Metal constituting the metal coating film is nickel.

A process for recovering gold from a gold-containing raw material, comprising leaching the gold-containing material with an aqueous solution comprising elemental bromine and bromide source to form a pregnant leach solution with the gold dissolved therein; separating said pregnant leach solution from the gold-depleted raw material, removing elemental bromine from said pregnant leach solution, extracting the gold from the pregnant leach solution in an acidic environment into an organic extractant, to form a gold-loaded extract and bromide-containing raffinate, stripping the extract with an alkaline aqueous solution to form a gold-bearing aqueous solution, generating gold (Au.sup.0) and treating bromide-containing stream(s) to produce recyclable elemental bromine.

A process for recovering gold from a gold-containing raw material, comprising leaching the gold-containing material with an aqueous solution comprising elemental bromine and bromide source to form a pregnant leach solution with the gold dissolved therein; separating said pregnant leach solution from the gold-depleted raw material, removing elemental bromine from said pregnant leach solution, extracting the gold from the pregnant leach solution in an acidic environment into an organic extractant, to form a gold-loaded extract and bromide-containing raffinate, stripping the extract with an alkaline aqueous solution to form a gold-bearing aqueous solution, generating gold (Au.sup.0) and treating bromide-containing stream(s) to produce recyclable elemental bromine.

Disclosed herein are methods and systems that relate to various configurations of electrochemical, bromination, oxybromination, bromine oxidation, hydrolysis, neutralization, and epoxidation reactions to form propylene bromohydrin, propanal, and propylene oxide or to form bromoethanol, bromoacetaldehyde, and ethylene oxide.

The present invention relates to an electrode assembly, electrode structures and an electrolyser using said assemblies/structures, and in particular provides an electrode assembly comprising an anode structure and a cathode structure, each of said anode structure and cathode structure comprising i) a flange which can interact with a flange on an another electrode structure to hold a separator in between the two, ii) an electrolysis compartment which contains an electrode, and which in use contains a liquid to be electrolysed, iii) an inlet for the liquid to be electrolysed and iv) an outlet header for evolved gas and spent liquid, wherein the outlet header on one of the anode structure and the cathode structure is an external outlet header and the outlet header on the other one of the anode structure and the cathode structure is an internal outlet header, as well as to electrolysers comprising a plurality of such electrode assemblies.