Abstract: An electrochemical cell includes a high voltage cathode configured to operate at 1.5 volts or greater; an anode including Mg0; and an electrolyte including an ether solvent and a magnesium salt; wherein: a concentration of the magnesium salt in the ether is 1 M or greater.

Abstract: An electrochemical cell includes a high voltage cathode configured to operate at 1.5 volts or greater; an anode including Mg0; and an electrolyte including an ether solvent and a magnesium salt; wherein: a concentration of the magnesium salt in the ether is 1 M or greater.

Abstract: In one preferred embodiment, a photocatalyst for conversion of carbon dioxide and water to a hydrocarbon and oxygen comprises at least one nanoparticulate metal or metal oxide material that is substantially free of a carbon coating, prepared by heating a metal-containing precursor compound in a sealed reactor under a pressure autogenically generated by dissociation of the precursor material in the sealed reactor at a temperature of at least about 600° C. to form a nanoparticulate carbon-coated metal or metal oxide material, and subsequently substantially removing the carbon coating. The precursor material comprises a solid, solvent-free salt comprising a metal ion and at least one thermally decomposable carbon- and oxygen-containing counter-ion, and the metal of the salt is selected from the group consisting of Mn, Ti, Sn, V, Fe, Zn, Zr, Mo, Nb, W, Eu, La, Ce, In, and Si.

Abstract: In one preferred embodiment, a photocatalyst for conversion of carbon dioxide and water to a hydrocarbon and oxygen comprises at least one nanoparticulate metal or metal oxide material that is substantially free of a carbon coating, prepared by heating a metal-containing precursor compound in a sealed reactor under a pressure autogenically generated by dissociation of the precursor material in the sealed reactor at a temperature of at least about 600° C. to form a nanoparticulate carbon-coated metal or metal oxide material, and subsequently substantially removing the carbon coating. The precursor material comprises a solid, solvent-free salt comprising a metal ion and at least one thermally decomposable carbon- and oxygen-containing counter-ion, and the metal of the salt is selected from the group consisting of Mn, Ti, Sn, V, Fe, Zn, Zr, Mo, Nb, W, Eu, La, Ce, In, and Si.

Abstract: Compressive composite seals for solid oxide fuel cell applications are provided. A compressive composite seal structure includes a glass phase to provide a gas tight seal, a reinforcing secondary phase to provide mechanical stability, and a compressive core. The compressive core is filled with an inert gas or air, providing a degree of compressibility, or alternatively is filled with a selected material to provide a more specific degree of compressibility and strength, such as a lower melting point glass. The compressive composite seal structure maintains an effective seal during the operating conditions of the SOFC. The self healing glass phase with the reinforcing secondary phase providing mechanical stability provides an elastic response at high temperature, effectively reduces crack propagation and if the temperature or pressure goes too high, the seal remains reliable and effective.

Abstract: A composition of matter and method of use of an electrode for intermediate temperature electrochemical devices. An electrode consists essentially of a perovskite based oxide having a composition of La1-xSr1-xMn1-yCryO3-? and the electrode can be used at intermediate operating temperatures of 650-800° C.