The present invention provides an electrocatalytic material and a method for making an electrocatalytic material. There is also provided an electrocatalytic material comprising amorphous metal or mixed metal oxides. There is also provided methods of forming an electrocatalyst, comprising an amorphous metal oxide film.

Electrodes useful in dye sensitized photoelectrosynthesis cells provide a coreshell nanoparticle having a chromophore and a catalyst, or a chromophore-catalyst assembly, linked to the shell material. Optionally, an overlayer stabilizes the chromophore or chromophore-catalyst assembly on the shell material. In some embodiments, the core material comprises tin oxide; the shell material comprises titanium dioxide; the chromophore-catalyst assembly includes [(PO.sub.3H.sub.2).sub.2bpy).sub.2Ru(4-Mebpy-4′-bimpy)Ru(tpy) (OH.sub.2)].sup.4+, and the overlayer comprises aluminum oxide or titanium dioxide.

Nanostructured carbide chemical compound is used to convert carbide to carbon. A method comprising: providing at least one carbide chemical compound and reducing a metal cation with use of the carbide chemical compound to form elemental carbon, wherein the carbide chemical compound is nanostructured. The nanostructured carbide chemical compound can be in the form of a nanoparticle, a nanowire, a nanotube, a nanofilm, a nanoline. The reactant can be a metal salt. Electrochemical reaction, or reaction in the melt or in solution, can be used to form the carbon. The nanostructured carbide chemical compound can be an electrode.

Nanostructured carbide chemical compound is used to convert carbide to carbon. A method comprising: providing at least one carbide chemical compound and reducing a metal cation with use of the carbide chemical compound to form elemental carbon, wherein the carbide chemical compound is nanostructured. The nanostructured carbide chemical compound can be in the form of a nanoparticle, a nanowire, a nanotube, a nanofilm, a nanoline. The reactant can be a metal salt. Electrochemical reaction, or reaction in the melt or in solution, can be used to form the carbon. The nanostructured carbide chemical compound can be an electrode.

The present invention provides a method for the generation of hydrogen, where the method comprises the step of reducing a mediator, such as a polyoxometallate, at a working electrode to yield a reduced mediator and generating oxygen at a counter electrode; and contacting the reduced mediator with a catalyst, such as a Pt, Rh, Pd, Mo or Ni containing catalyst, thereby to oxidise the reduced mediator to yield hydrogen.

The present invention provides a method for the generation of hydrogen, where the method comprises the step of reducing a mediator, such as a polyoxometallate, at a working electrode to yield a reduced mediator and generating oxygen at a counter electrode; and contacting the reduced mediator with a catalyst, such as a Pt, Rh, Pd, Mo or Ni containing catalyst, thereby to oxidise the reduced mediator to yield hydrogen.

System comprising an element for capturing and transforming external light into electricity based on the use of doped graphene; an electricity management control board to which are connected: a battery and a generator for supplying the current needed by a hydrolysis machine connected to the generator; a hydrogen tank connected to the hydrolysis machine; an oxygen tank connected to the hydrolysis machine, for use in space-based systems, which can be vented through an exhaust; a fuel cell or hydrogen cell connected to the hydrogen and oxygen tanks and a water deposit connected on one side to the hydrogen cell from which it receives the water generated and on the other to the hydrolysis machine to which it supplies the water. A self-sufficient or autonomous generation system is achieved.

The present disclosure provides a fuel production method and a fuel production apparatus which efficiently convert solar light energy into a fuel. The fuel production apparatus of the present disclosure includes a laminate, an electrolytic bath, and a support tool or a proton permeable membrane. The laminate includes a photoelectromotive layer having a p-n junction structure, a cathode electrode, an anode electrode and a side surface insulating layer, and the photoelectromotive layer includes a semiconductor layer that absorbs light in a near-infrared region with a wavelength of 900 nm or more. In the fuel production apparatus, an underwater optical path length is set to an optimum design value, so that even light in a near-infrared region with a wavelength of 900 nm or more is sufficiently utilized to efficiently convert light energy into at least one fuel selected from hydrogen, carbon monoxide, formic acid, methane, ethylene, methanol, ethanol, isopropanol, allyl alcohol, acetaldehyde and propionaldehyde through a reduction reaction on the cathode electrode.

Compositions comprising hydrogenated and dehydrogenated graphite comprising a plurality of flakes. At least one flake in ten has a size in excess of ten square micrometers. For example, the flakes can have an average thickness of 10 atomic layers or less.

Compositions comprising hydrogenated and dehydrogenated graphite comprising a plurality of flakes. At least one flake in ten has a size in excess of ten square micrometers. For example, the flakes can have an average thickness of 10 atomic layers or less.