Abstract: An electrochemical reaction device comprises: an electrolytic solution tank including a first region, a second region, and a path; a reduction electrode disposed in the first region; an oxidation electrode disposed in the second region; and a power source connected to the reduction electrode and oxidation electrode; and a plurality of ion exchange membranes separating the first region and the second region.

Abstract: An electrochemical reaction device includes: an electrolytic solution tank including a first storage part storing a first electrolytic solution and a second storage part storing a second electrolytic solution; a reduction electrode immersed in the first electrolytic solution; and an oxidation electrode immersed in the second electrolytic solution. The second electrolytic solution contains a substance to be oxidized. The first electrolytic solution has a first liquid phase containing water and a second liquid phase containing an organic solvent and being in contact with the first liquid phase. At least one liquid phase of the first liquid phase or the second liquid phase contains a substance to be reduced and is in contact with the reduction electrode.

Abstract: A reduction electrode of an embodiment includes a metal base material and a plurality of metal nanowires provided on the metal base material. The plurality of metal nanowires include metal nanowires whose average height of contour curve of surface is 20 nm or less for 50% or more in a number ratio. The plurality of metal nanowires are formed by reducing a plurality of metal oxides each having a nanowire shape formed on the metal base material by an electrochemical reduction method. A reduction process of the metal oxides includes a first process of passing a current under a constant current condition where an absolute value is 5 mA/cm2 or more through the plurality of metal oxides, and a second process of passing a current under a constant potential condition through the plurality of metal oxides.

Abstract: A photoelectrochemical reaction device of an embodiment includes: a first stack including a first electrode, a second electrode, and a photovoltaic layer provided therebetween; a second stack including a third electrode electrically connected to the first electrode, a fourth electrode electrically connected to the second electrode, and an ion migration layer provided therebetween; and an electrolytic solution tank storing a first electrolytic solution in which the third electrode is immersed and a second electrolytic solution in which the fourth electrode is immersed. One of the third and fourth electrodes causes an oxidation reaction, and the other of the third and fourth electrodes causes a reduction reaction. The third and fourth electrodes have ion permeability. An area of the second stack is larger than that of the first stack.

Abstract: According to one embodiment of a CO2 reduction catalyst of the present invention, a conductive material is immersed in an aqueous solution containing a gold source, and a current or a potential is applied, whereby a highly active CO2 reduction catalyst can be formed in a wide range portion on a surface of the conductive material. According to one embodiment of a CO2 reduction catalyst of the present invention, in a CO2 reduction reaction apparatus including a CO2 reduction electrode having the CO2 reduction catalyst, CO2 is reduced.

Abstract: An electrochemical reaction device includes: a first electrolytic solution tank having a first storage part and a second storage part; a second electrolytic solution tank having a third storage part and a fourth storage part; a first reduction electrode layer immersed in a first electrolytic solution; a first oxidation electrode layer immersed in a second electrolytic solution; a first generator electrically connected to the first reduction electrode and the first oxidation electrode layer; a second reduction electrode layer immersed in a third electrolytic solution; a second oxidation electrode layer immersed in a fourth electrolytic solution; a second generator electrically connected to the second reduction electrode and the second oxidation electrode layer; and at least one flow path out of a first flow path connecting the first storage part and the fourth storage part and a second flow path connecting the second storage part and the third storage part.

Abstract: Disclosed here is a method of operating a chemical reaction device that includes the steps of determining the presence of surplus power more than a demand, and determining the presence of solar energy.

Abstract: A system, comprising: a file server coupled to a plurality of client terminals; and an archive server coupled to the file server via a network. The file server is configured to: provide an area for storing data recognizable by each of the plurality of client terminals; determine whether to store first data into the first storage device based on an attribute of a first storage area in a case where an addition request for storing the first data into the first storage area is received from a client terminal; and transmit the addition request to the archive server. The archive server is configured to store the first data into the second storage device in a case where the addition request is received.

Abstract: According to one embodiment, a reduction catalyst includes a current collector including a metal layer; and organic molecules including a quaternary nitrogen cation, which are bonded to the metal layer. The organic molecules are represented by any of the following general formulae I to V.

Abstract: A carbon dioxide electrolytic device comprises: an electrolysis cell including a cathode, an anode, a carbon dioxide source to supply carbon dioxide to the cathode, a solution source to supply an electrolytic solution, and a separator separating the anode and the cathode; a power controller connected to the anode and the cathode; a refresh material source including a gas source to supply a gaseous substance, and a solution source to supply a rinse solution; and a controller to control the carbon dioxide source, the solution source, the power controller, and the refresh material source in accordance with request criteria of a performance of the cell and thus stop the supply of the carbon dioxide and the electrolytic solution, and apply the voltage therebetween while supplying the rinse solution thereto.

Abstract: A reduction catalyst body for carbon dioxide of an embodiment includes a metal layer, and a projection provided on the metal layer. The projection is constituted of an aggregate of fine metal particles, and possesses a polyhedral structure having surfaces of three faces or more of a polygon. The projection has a site of reducing carbon dioxide, as at least a part of the surfaces.

Abstract: An electrochemical reaction device, comprises: an anode to oxidize a first substance; a first flow path facing on the anode and through which a liquid containing the first substance flows; a cathode to reduce a second substance; a second flow path facing on the cathode and through which a gas containing the second substance flows; a porous separator provided between the anode and the cathode; and a power supply connected to the anode and the cathode. A thickness of the porous separator is 1 ?m or more and 500 ?m or less. An average fine pore size of the porous separator is larger than 0.008 ?m and smaller than 0.45 ?m. A porosity of the porous separator is higher than 0.5.

Abstract: To convert light into a chemical substance with high conversion efficiency. A device, comprising: a photovoltaic layer having a first face and a second face; an oxidation electrode layer electrically connected to the first face of the photovoltaic layer; a reduction electrode layer electrically connected to the second face of the photovoltaic layer; a first electrolytic solution being supplied to the oxidation electrode layer; a second electrolytic solution being supplied to the reduction electrode layer; and a porous layer, provided to in contact with at least one of the first electrolytic solution and the second electrolytic solution, having fine pores through which a product produced by the oxidation reaction or the reduction reaction passes, and being given a temperature gradient wherein the product being purified by the porous layer.

Abstract: An electrochemical reaction device, includes: an electrolytic solution tank including a first storage part to store a first electrolytic solution containing carbon dioxide, and a second storage part to store a second electrolytic solution containing Water: a reduction electrode disposed in the first storing part; an oxidation electrode disposed in the second storing part; a porous both disposed in the first storing part; and a flow path connecting the porous body and an outside of the electrolytic solution tank to supply gas containing carbon dioxide to the porous body.

Abstract: A carbon dioxide electrolytic device of an embodiment includes: an electrolysis cell including a cathode, an anode, a carbon dioxide supply unit, an electrolytic solution supply unit, and a separator; a power supply; a reaction control unit which causes a reduction reaction and an oxidation reaction by passing an electric current from the power supply to the anode and the cathode; a refresh material supply unit including a gas supply unit which supplies a gaseous substance to at least one of the anode and the cathode; and a refresh control unit which stops supply of the current from the power supply and supply of carbon dioxide and an electrolytic solution, and operates the refresh material supply unit, based on request criteria of a cell output of the electrolysis cell.

Abstract: According to one embodiment, a reduction catalyst includes a charge collector having a metal layer on a surface; and a modified organic molecule bound to a surface of the metal layer and containing a quaternary nitrogen cation.

Abstract: A method of manufacturing a photoelectrode of an embodiment includes: preparing a stack including a first electrode layer having a light transmitting electrode, a second electrode layer having a metal electrode, and a photovoltaic layer disposed between the electrode layers; immersing the stack in an electrolytic solution containing an ion including a metal constituting a catalyst layer which is to be formed on the first electrode layer; and passing a current to the stack through the second electrode layer to electrochemically precipitate at least one selected from the metal and a compound containing the metal, onto the first electrode layer, thereby forming the catalyst layer.

Abstract: According to one embodiment, an oxidation electrode includes: a collector; an oxidation catalyst formed on the collector; and a modified organic molecule which is bonded to the surface of the oxidation catalyst, and comprises a cationic functional group.

Abstract: An electrochemical reaction device of an embodiment includes: a reaction tank which includes a first storage storing a first electrolytic solution containing carbon dioxide, and a second storage storing a second electrolytic solution containing water; a reduction electrode which is disposed at the first storage, an oxidation electrode which is disposed at the second storage; a counter electrode which is used for potential sweep using the reduction electrode as a working electrode; a first power supply which is electrically connected to the reduction electrode and the oxidation electrode, to generate a reduction reaction and an oxidation reaction; and a second power supply which is electrically connected to the reduction electrode and the counter electrode, to sweep a potential while setting an oxidation potential of the reduction electrode or less as an upper limit potential.