Processes for converting nitrate to ammonia are described. Nitrate is electrochemically converted in the presence of a catalyst to form a product comprising ammonia. The catalyst comprises cobalt on a support, where the support is in the form of a foil, mesh, cloth, gauze, sponge, and combinations thereof. The catalyst may alternatively comprise a cobalt in the form of a foil, mesh, cloth, gauze, sponge, and combinations thereof.

Processes for converting nitrate to ammonia are described. Nitrate is electrochemically converted in the presence of a catalyst to form a product comprising ammonia. The catalyst comprises cobalt on a support, where the support is in the form of a foil, mesh, cloth, gauze, sponge, and combinations thereof. The catalyst may alternatively comprise a cobalt in the form of a foil, mesh, cloth, gauze, sponge, and combinations thereof.

A porous solid electrolyte electrosynthesis cell and corresponding related process for the direct synthesis of high purity liquid products wherein the electrosynthesis cell comprises a cathode compartment including a cathode electrode comprising a gas diffusion layer loaded with a selective reduction reaction electrocatalyst for specific reduction reactions. The electrosynthesis cell further includes an anode compartment including an anode electrode comprising a gas diffusion layer loaded with a catalyst for oxidation reactions; and a solid electrolyte compartment comprising a porous solid electrolyte; a cation exchange membrane; and an anion exchange membrane; (or two cation exchange membranes) wherein the solid electrolyte compartment is separated from the cathode and the anode by the anion exchange membrane and the cation exchange membrane (or by the two cation exchange membranes).

A porous solid electrolyte electrosynthesis cell and corresponding related process for the direct synthesis of high purity liquid products wherein the electrosynthesis cell comprises a cathode compartment including a cathode electrode comprising a gas diffusion layer loaded with a selective reduction reaction electrocatalyst for specific reduction reactions. The electrosynthesis cell further includes an anode compartment including an anode electrode comprising a gas diffusion layer loaded with a catalyst for oxidation reactions; and a solid electrolyte compartment comprising a porous solid electrolyte; a cation exchange membrane; and an anion exchange membrane; (or two cation exchange membranes) wherein the solid electrolyte compartment is separated from the cathode and the anode by the anion exchange membrane and the cation exchange membrane (or by the two cation exchange membranes).

A process provides an unlimited source of ammonia, for primary use as a liquid disinfectant for application directly to human hands or to hand wipes, by combining a carbon nanospike catalyst with a copper catalyst, carbon dioxide, water and water vapor in an electrochemical process initiated by a power source. And a process for making urea by addition of carbon dioxide. Further, an improved process provides for making the carbon nanospike, through injection with photons and electromagnetic waves.

A process provides an unlimited source of ammonia, for primary use as a liquid disinfectant for application directly to human hands or to hand wipes, by combining a carbon nanospike catalyst with a copper catalyst, carbon dioxide, water and water vapor in an electrochemical process initiated by a power source. And a process for making urea by addition of carbon dioxide. Further, an improved process provides for making the carbon nanospike, through injection with photons and electromagnetic waves.

A process provides an unlimited source of ethanol, for primary use as a liquid disinfectant for application directly to human hands or to hand wipes, by combining a carbon nanospike catalyst with a copper catalyst, carbon dioxide, water and water vapor, and injection of photons and electromagnetic waves, in an electrochemical process initiated by a power source. The process also provides an unlimited source for hydrogen peroxide and ammonia. Further, the application provides an improved process for making the carbon nanospike, through injection with photons and electromagnetic waves.

Disclosed is an Offshore Energy Generation System (OEGS), zero greenhouse gases emissions during operations, earthquake and tsunami proof, nuclear meltdown safe, floating ship-shaped, moored. The INVENTION delivers clean energy in the form of electricity and/or ammonia (NH.sub.3) and freshwater to offshore or onshore consumers. The INVENTION is effective, affordable and reliable solution for the global climate change and the freshwater scarcity crisis. By deploying this INVENTION across the world, the net zero emissions targets from IPCC can be achieved and the water scarcity crisis mitigated. The INVENTION enables better safety of the population served, optimal use of land, eliminate land use conflicts and enables the protection of the world cultural heritage. The INVENTION comprises of an electric power generation system based on nuclear or hydrogen (H.sub.2) fuel cells, ammonia generation, freshwater generation, offshore cranes, data processing centers, blockchain, helideck, telecommunications system, automation and control system, nitrogen and hydrogen generation systems.

This invention describes a novel recovery method of ammonia through the electrocoagulation process, which may be applied in the industrial as well as the environmental sectors. The present invention has a significant impact not only on recovering the ammonia content from the Solvay effluent, but also for recovering the ammonia from landfill leachate and different sources of wastewater where high concentrations of ammonia can be found. This invention has economic benefits in recovering ammonia and reducing the required energy in such processes. Another impact is the environmental one, where ammonia can cause problems such as toxicity to the organisms living in the soil or water bodies, and could also decrease the concentration of the dissolved oxygen.

This invention describes a novel recovery method of ammonia through the electrocoagulation process, which may be applied in the industrial as well as the environmental sectors. The present invention has a significant impact not only on recovering the ammonia content from the Solvay effluent, but also for recovering the ammonia from landfill leachate and different sources of wastewater where high concentrations of ammonia can be found. This invention has economic benefits in recovering ammonia and reducing the required energy in such processes. Another impact is the environmental one, where ammonia can cause problems such as toxicity to the organisms living in the soil or water bodies, and could also decrease the concentration of the dissolved oxygen.