Included are an oxidation electrode that is formed in a film state on a transparent substrate and receives light from the outside, an oxidation bath that holds an electrolytic solution in which the oxidation electrode is immersed, a reduction electrode, a reduction bath that holds the electrolytic solution, in which the reduction electrode is immersed and which is subjected to bubbling with carbon dioxide from the outside, an electrolyte membrane that is disposed between the oxidation bath and the reduction bath and divides the electrolytic solution into an oxidation side and a reduction side, and a thermoelectric element including a heat absorbing plate that faces the transparent substrate, receives light transmitted through the transparent substrate, and converts the light into heat, including a heat radiation plate that faces the heat absorbing plate and radiates the heat of the heat absorbing plate, including thermoelectric materials interposed between the heat absorbing plate and the heat radiation plate.

Included are an oxidation electrode that is formed in a film state on a transparent substrate and receives light from the outside, an oxidation bath that holds an electrolytic solution in which the oxidation electrode is immersed, a reduction electrode, a reduction bath that holds the electrolytic solution, in which the reduction electrode is immersed and which is subjected to bubbling with carbon dioxide from the outside, an electrolyte membrane that is disposed between the oxidation bath and the reduction bath and divides the electrolytic solution into an oxidation side and a reduction side, and a thermoelectric element including a heat absorbing plate that faces the transparent substrate, receives light transmitted through the transparent substrate, and converts the light into heat, including a heat radiation plate that faces the heat absorbing plate and radiates the heat of the heat absorbing plate, including thermoelectric materials interposed between the heat absorbing plate and the heat radiation plate.

A thin plate-shaped graphite product is produced by applying a current to an electrochemical reaction system including a graphite-containing anode, a cathode optionally containing graphite, and an electrolyte solution containing tetrafluoroboric acid or hexafluorophosphoric acid as an electrolyte. Flaky graphite is produced by subjecting the thin plate-shaped graphite product to delamination.

Provided herein are methods of preparing tetrahexahedra nanoparticles and methods of using the tetrahexahedra nanoparticles as an oxidative catalyst.

Provided herein are methods of preparing tetrahexahedra nanoparticles and methods of using the tetrahexahedra nanoparticles as an oxidative catalyst.

A metal sulfate manufacturing system comprising an electrochemical dissolution system having, an anode electrode that holds metal raw material, a cathode electrode, an electrolyte bath having an inlet to receive an initial acid or metal-acid complex solution and an outlet to discharge the treated metal sulfate solution, stirring equipment that mixes the electrolyte bath, a temperature control system, and a rectifier that supplies current at constant voltage between the anode and cathode electrode.

A metal sulfate manufacturing system comprising an electrochemical dissolution system having, an anode electrode that holds metal raw material, a cathode electrode, an electrolyte bath having an inlet to receive an initial acid or metal-acid complex solution and an outlet to discharge the treated metal sulfate solution, stirring equipment that mixes the electrolyte bath, a temperature control system, and a rectifier that supplies current at constant voltage between the anode and cathode electrode.

A method for manufacturing a sulfuric acid solution includes supplying a chloride ion-containing sulfuric acid solution as an initial electrolyte in an electrolyzer inside of which is divided into an anode chamber and a cathode chamber by a diaphragm; and subsequently taking out a metal dissolved electrolyte in which a metal constituting the anode is dissolved from the anode chamber while supplying a current to an anode and a cathode disposed in the electrolyzer.

The present disclosure relates to the technical field of nano materials and aims to provide to a method for preparing nano-graphene oxide by electrochemically exfoliating a carbon fiber material. The method includes the following steps: building an electrochemical reaction system by using a raw material with a carbon fiber as a basic structural unit as an anode, a metal or graphitic carbon material as a cathode, and a phosphate buffer solution with a neutral pH as an electrolyte; in an electrolysis process, gradually exfoliating a carbon fiber in the anode raw material and dispersing the carbon fiber in the electrolyte solution to generate graphene oxide; centrifuging to separate the reacted electrolyte solution, taking upper dispersion liquid, and washing away residual anions and cations; and performing ultrasonic treatment to obtain nano-graphene oxide dispersed in water and free of impurities.

The present disclosure relates to the technical field of nano materials and aims to provide to a method for preparing nano-graphene oxide by electrochemically exfoliating a carbon fiber material. The method includes the following steps: building an electrochemical reaction system by using a raw material with a carbon fiber as a basic structural unit as an anode, a metal or graphitic carbon material as a cathode, and a phosphate buffer solution with a neutral pH as an electrolyte; in an electrolysis process, gradually exfoliating a carbon fiber in the anode raw material and dispersing the carbon fiber in the electrolyte solution to generate graphene oxide; centrifuging to separate the reacted electrolyte solution, taking upper dispersion liquid, and washing away residual anions and cations; and performing ultrasonic treatment to obtain nano-graphene oxide dispersed in water and free of impurities.