A process for preparing or regenerating peroxodisulfuric acid and its salts by electrolysis of an aqueous solution containing sulfuric acid and/or metal sulfates at diamond-coated electrodes without addition of promoters is described, with bipolar silicon electrodes which are coated with diamond on one side and whose uncoated silicon rear side serves as cathode being used.

A boron-doped diamond electrode with an ultra-high specific surface area, and a preparation method therefor and the application thereof are provided. The boron-doped diamond electrode includes a substrate and an electrode working layer arranged on a surface thereof, the substrate is polysilicon or monocrystal silicon with a high specific surface area, and the electrode working layer is a boron-doped diamond layer. The polysilicon with a high specific surface area is obtained by anisotropIc etching and/or isotropic etching, and the monocrystal silicon with a high specific surface area is obtained by anisotropic etching. The boron-doped diamond layer includes a highly conductive layer, a corrosion-resistant layer, and a strongly electrocatalytically active layer, which have different boron contents. Compared with a traditional plate electrode, the present disclosure has a low cost and an extremely high specific surface area, provides a larger current intensity with a lower current density, and has broad application prospects.

A boron-doped diamond electrode with an ultra-high specific surface area, and a preparation method therefor and the application thereof are provided. The boron-doped diamond electrode includes a substrate and an electrode working layer arranged on a surface thereof, the substrate is polysilicon or monocrystal silicon with a high specific surface area, and the electrode working layer is a boron-doped diamond layer. The polysilicon with a high specific surface area is obtained by anisotropIc etching and/or isotropic etching, and the monocrystal silicon with a high specific surface area is obtained by anisotropic etching. The boron-doped diamond layer includes a highly conductive layer, a corrosion-resistant layer, and a strongly electrocatalytically active layer, which have different boron contents. Compared with a traditional plate electrode, the present disclosure has a low cost and an extremely high specific surface area, provides a larger current intensity with a lower current density, and has broad application prospects.

Methods and systems for removing impurities from an electrolytic salt are disclosed. After removal of impurities from the salt, the salt can be subjected to electrorefining to produce high-purity materials, for example silicon. Impurities are removed from the salt using a system that includes a first working electrode, a counter electrode, and at least one reference electrode. A second working electrode can also be utilized. The salt may be utilized in an electrorefining system, for example a system operated in a single phase or multiple phase operation to produce high-purity materials, such as solar-grade silicon.

An electrode having an embedded charge contains a substrate, a first electronic charge trap defined at the interface of a first insulating layer and a second insulating layer; and a first conductive layer disposed on the first electronic charge trap; wherein the first conductive layer contains a conductive material configured to permit an external electric field to penetrate the electrode from the first electronic charge trap; and wherein the first insulating layer is not the same as the second insulating layer.

In accordance with the principals of the present invention, an electrolytic generator and method of electrolytic generation are provided. An electrolytic stack includes of a first electrode, a second electrode, and a polymer-electrolyte membrane placed between the first and second electrodes. A first fluid passage provides fluid passage over the first electrode while a second fluid passage provides fluid passage over the second electrode. A third fluid passage provides fluid connection between the first fluid passage and the second fluid passage such that the fluid flows from the first fluid passage to the second fluid passage via the third fluid passage. An electronic current is provided between the first electrode and the second electrode when a voltage bias is applied to the electrodes.

Provided is a photocathode structure including: a photocathode including silicon (Si); an intermediate layer formed on the photocathode, and including a silicon oxide (SiO.sub.x); and a protective layer foiled on the intermediate layer, and including a metal oxide, wherein the intermediate layer is a tunneling barrier configured to transfer charges from the photocathode to the protective layer by an electric field applied from an outside.

Provided is a photocathode structure including: a photocathode including silicon (Si); an intermediate layer formed on the photocathode, and including a silicon oxide (SiO.sub.x); and a protective layer foiled on the intermediate layer, and including a metal oxide, wherein the intermediate layer is a tunneling barrier configured to transfer charges from the photocathode to the protective layer by an electric field applied from an outside.

An electrode having an embedded charge contains a substrate, a first electronic charge trap defined at the interface of a first insulating layer and a second insulating layer; and a first conductive layer disposed on the first electronic charge trap; wherein the first conductive layer contains a conductive material configured to permit an external electric field to penetrate the electrode from the first electronic charge trap; and wherein the first insulating layer is not the same as the second insulating layer.

The invention relates to a process for the oxidation of carbon-containing organic compounds where the said compounds have at least one bond with a bond order >1, wherein an oxidizing of these carbon-containing organic compounds to be oxidized is performed with electrochemically generated C—O—O oxidizing agents, in particular peroxodicarbonate. Also described is the use of C—O—O oxidizing agents generated electrochemically from carbonate, in particular peroxodicarbonate, as oxidizing agents for the oxidation of carbon-containing organic compounds, in particular carbon-containing organic compounds where the said compounds have at least one bond with a bond order >1. Finally, an arrangement for the oxidation of carbon-containing organic compounds is provided, comprising a first unit for the electrochemical preparation of C—O—O oxidizing agents generated electrochemically from carbonate, in particular peroxodicarbonate, and a second unit for the oxidizing of the carbon-containing organic compound with the C—O—O oxidizing agent generated electrochemically from carbonate, in particular peroxodicarbonate. In this case, these two units are connected to one another in such a way that an ex situ generated oxidizing agent can be fed to the second unit.