Provided is a separator for a fuel cell that can suppress a decrease in the power generation performance of the fuel cell by reducing the contact resistance of the separator. Specifically, provided is a separator for a fuel cell, the separator being adapted to be in contact with a MEGA (power generation portion) including a membrane electrode assembly of the fuel cell so as to separate the MEGA from a MEGA of an adjacent fuel cell, the separator including a metal substrate made of metal; and a tin oxide film covering a surface of the metal substrate on the side of the MEGA. The tin oxide film is made of tin oxide containing 1 to 10 atom % of aluminum.

Provided is a separator for a fuel cell that can suppress a decrease in the power generation performance of the fuel cell by reducing the contact resistance of the separator. Specifically, provided is a separator for a fuel cell, the separator being adapted to be in contact with a MEGA (power generation portion) including a membrane electrode assembly of the fuel cell so as to separate the MEGA from a MEGA of an adjacent fuel cell, the separator including a metal substrate made of metal; and a tin oxide film covering a surface of the metal substrate on the side of the MEGA. The tin oxide film is made of tin oxide containing 1 to 10 atom % of aluminum.

ADVANCED AUTOMATED FABRICATION SYSTEM AND METHODS FOR THERMAL AND MECHANICAL COMPONENTS UTILIZING QUADRATIC OR SQUARED HYBRID DIRECT LASER SINTERING, DIRECT METAL LASER SINTERING, CNC, THERMAL SPRAYING, DIRECT METAL DEPOSITION AND FRICTIONAL STIR WELDING. CROSS-REFERENCE TO RELATED APPLICATIONS

A composite membrane includes an ion-conductive polymer layer; and a plurality of gas blocking inorganic particles non-continuously aligned on the ion-conductive polymer layer, wherein the composite membrane has a radius of curvature of about 10 millimeters or less.

A composite membrane includes an ion-conductive polymer layer; and a plurality of gas blocking inorganic particles non-continuously aligned on the ion-conductive polymer layer, wherein the composite membrane has a radius of curvature of about 10 millimeters or less.

A means for imparting low contact resistance and excellent corrosion resistance under highly corrosive environments, such as environments in the presence of a fluoride ion, to a separator for fuel batteries includes a separator for fuel batteries including a metal base material and a tin oxide film formed on a surface of the metal base material, in which the tin oxide film is tin oxide containing zirconium, and an element ratio of zirconium to tin (Zr/Sn) is in a range of 0.10 to 0.70.

A means for imparting low contact resistance and excellent corrosion resistance under highly corrosive environments, such as environments in the presence of a fluoride ion, to a separator for fuel batteries includes a separator for fuel batteries including a metal base material and a tin oxide film formed on a surface of the metal base material, in which the tin oxide film is tin oxide containing zirconium, and an element ratio of zirconium to tin (Zr/Sn) is in a range of 0.10 to 0.70.

A solid oxide fuel cell (SOFC) stack including a plurality of SOFCs and a plurality of interconnects. Each interconnect is located between two adjacent SOFCs, and each interconnect contains a Mn or Co containing, electrically conductive metal oxide layer on an air side of the interconnect. The SOFC stack also includes a barrier layer located between the electrically conductive metal oxide layer and an adjacent SOFC. The barrier layer is configured to prevent Mn or Co diffusion from the electrically conductive metal oxide layer to the adjacent SOFC.

A solid oxide fuel cell (SOFC) stack including a plurality of SOFCs and a plurality of interconnects. Each interconnect is located between two adjacent SOFCs, and each interconnect contains a Mn or Co containing, electrically conductive metal oxide layer on an air side of the interconnect. The SOFC stack also includes a barrier layer located between the electrically conductive metal oxide layer and an adjacent SOFC. The barrier layer is configured to prevent Mn or Co diffusion from the electrically conductive metal oxide layer to the adjacent SOFC.

An interconnect for a fuel cell stack includes an interconnect body having an air surface having air flow channels and ribs and a fuel surface having fuel flow channels and ribs, an electrically conductive contact layer located on the air surface of the interconnect, the electrically conductive contact layer containing at least one of Co and Mn, and a corrosion barrier layer containing zirconium silicate and magnesium aluminosilicate crystals located over the electrically conductive contact layer.