A containerised modular electrochemical cell system, comprising: a housing; and a plurality of electrochemical stacks removably mounted within said housing, each stack comprising: one or more electrochemical cells; one or more fluid inlet(s) for receiving feedstock; and one or more product outlet(s), wherein the stacks are arranged in at least one string, each string comprising two or more of the stacks, the stacks in each string being electrically connectable in series, and each string being connectable to a power source, and wherein each stack or string is configured to be independently activated; and wherein each string comprises: at least one feedstock inlet manifold fluidly coupled to the inlet(s) of the stacks of the string for distributing feedstock between the inlet(s) of the stacks, and at least one product outlet manifold fluidly coupled to the outlet(s) of the stacks of the string; and flow regulation means configured to regulate fluid flow through the inlet(s) and/or outlet(s).

A containerised modular electrochemical cell system, comprising: a housing; and a plurality of electrochemical stacks removably mounted within said housing, each stack comprising: one or more electrochemical cells; one or more fluid inlet(s) for receiving feedstock; and one or more product outlet(s), wherein the stacks are arranged in at least one string, each string comprising two or more of the stacks, the stacks in each string being electrically connectable in series, and each string being connectable to a power source, and wherein each stack or string is configured to be independently activated; and wherein each string comprises: at least one feedstock inlet manifold fluidly coupled to the inlet(s) of the stacks of the string for distributing feedstock between the inlet(s) of the stacks, and at least one product outlet manifold fluidly coupled to the outlet(s) of the stacks of the string; and flow regulation means configured to regulate fluid flow through the inlet(s) and/or outlet(s).

Methods and systems for degradation of polymeric and non-polymeric substances is provided. An example method includes generating structurally altered gas molecules from water, where the structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the water. The method further includes infusing the structurally altered gas molecules into a matter containing the polymeric substances and the non-polymeric substances, where upon being infused, the structurally altered gas molecules cause a decrease in concentration of the polymeric substances and the non-polymeric substances in the matter.

Methods and systems for degradation of polymeric and non-polymeric substances is provided. An example method includes generating structurally altered gas molecules from water, where the structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the water. The method further includes infusing the structurally altered gas molecules into a matter containing the polymeric substances and the non-polymeric substances, where upon being infused, the structurally altered gas molecules cause a decrease in concentration of the polymeric substances and the non-polymeric substances in the matter.

The present invention provides MEC stack with several or multiple MEC cells comprising at least one gas inlet and at least one degassing element as well as methods to improve the bio-electromethanation reaction catalysed by bio catalysts in these MEC stacks.

The present invention provides MEC stack with several or multiple MEC cells comprising at least one gas inlet and at least one degassing element as well as methods to improve the bio-electromethanation reaction catalysed by bio catalysts in these MEC stacks.

An electrochemical cell comprises an anode, an anode electrolyte solution in contact with the anode, wherein the anode electrolyte solution has a first pH, a cathode comprising an ionomer, a cathode electrolyte solution in contact with the cathode wherein the cathode electrolyte solution has a second pH, and a separator positioned between the anode and the cathode, wherein the electrochemical cell is configured to maintain a pH differential between the first pH and the second pH.

An electrochemical cell comprises an anode, an anode electrolyte solution in contact with the anode, wherein the anode electrolyte solution has a first pH, a cathode comprising an ionomer, a cathode electrolyte solution in contact with the cathode wherein the cathode electrolyte solution has a second pH, and a separator positioned between the anode and the cathode, wherein the electrochemical cell is configured to maintain a pH differential between the first pH and the second pH.

The present disclosure discloses a method for preparing a carbon nanodot-modified nickel phosphide nanosheet and a use thereof as auxiliary materials in water electrolysis. The preparation steps include: preparing water solution containing carbon nanodots; attaching the carbon nanodots to the surface of a hydrogen-producing electrode in water electrolysis; and annealing the hydrogen-producing electrode with carbon nanodots. The carbon nanodots obtained by this preparation method have extremely small sizes and relatively uniform diameters, facilitating the attachment with other materials, and the integration of these carbon nanodots with the hydrogen-producing electrode in water electrolysis significantly enhances the hydrogen production efficiency, substantially reducing the cost required for hydrogen production through water electrolysis.

The present disclosure discloses a method for preparing a carbon nanodot-modified nickel phosphide nanosheet and a use thereof as auxiliary materials in water electrolysis. The preparation steps include: preparing water solution containing carbon nanodots; attaching the carbon nanodots to the surface of a hydrogen-producing electrode in water electrolysis; and annealing the hydrogen-producing electrode with carbon nanodots. The carbon nanodots obtained by this preparation method have extremely small sizes and relatively uniform diameters, facilitating the attachment with other materials, and the integration of these carbon nanodots with the hydrogen-producing electrode in water electrolysis significantly enhances the hydrogen production efficiency, substantially reducing the cost required for hydrogen production through water electrolysis.