Dual function composite oxygen transport membrane

We claim: 1. A dual function composite oxygen transport membrane, said dual function membrane comprising: a porous substrate having a first side and an opposing side, a plurality of mixed conducting oxygen transport layers, and a catalyst layer for catalyzing endothermic reactions, wherein the plurality of mixed conducting oxygen transport layers are formed on the first side of the porous substrate and the catalyst layer is coated on the opposing second side of the porous substrate, wherein a thickness of the catalyst layer is at least 10 microns. 2. The dual function composite oxygen transport membrane of claim 1 wherein said plurality of mixed conducting oxygen transport layers form a layered structure comprising a dense layer, an intermediate porous layer located between the dense layer and the porous substrate, and an optional surface exchange layer over the dense layer wherein each of the dense layer and the intermediate porous layer and the surface exchange layer are capable of conducting oxygen ions and electrons at operational temperatures. 3. The dual function composite oxygen transport membrane of claim 2 wherein said layered structure formed on the first side of the porous substrate separates oxygen from an oxygen containing gas stream in contact with the layered structure when operational at operational temperatures and provide said separated oxygen for reaction with a combustible substance diffusing through the catalyst layer formed on the opposing second side of said porous substrate. 4. The dual function composite oxygen transport membrane of claim 1 wherein, the thickness of said catalyst layer is in the range of about 40 microns to about 80 microns. 5. The dual function composite oxygen transport membrane of claim 1 wherein the catalyst layer contains one or more of nickel, rhodium, platinum, ruthenium, or palladium. 6. The dual function composite oxygen transport membrane of claim 1 wherein the catalyst layer is formed using precursors of nickel or rhodium or platinum or ruthenium or palladium or mixtures of two or more thereof. 7. The dual function composite oxygen transport membrane of claim 1 wherein the catalyst layer is formed using a perovskite material containing Ruthenium. 8. The dual function composite oxygen transport membrane of claim 1 further comprising the porous substrate configured as a substantially tubular structure wherein the plurality of mixed conducting oxygen transport layers are formed on the outside surface of said tubular structure and the catalyst layer is formed on the inside surface of said tubular structure. 9. A method of forming a dual function composite oxygen transport membrane, said method comprising: providing a porous substrate having a first side and an opposing second side; forming a layer structure of mixed conducting materials in a sintered state on the first side of the porous substrate, coating a catalyst layer on the opposing second side of the porous substrate for catalyzing endothermic reactions, wherein a thickness of the catalyst layer is at least 10 microns. 10. The method of claim 9 wherein the layered structure of mixed conducting materials comprises an intermediate porous layer, a dense layer, and an optional surface exchange layer, and the forming of the dense layer and the forming of the catalyst layer is carried out in separate steps. 11. A method of forming a dual function composite oxygen transport membrane, said method comprising: providing a porous substrate having a first side and an opposing second side; forming an intermediate porous layer on the first side of the porous substrate; forming a dense layer over the intermediate porous layer, forming a surface exchange layer over the dense layer, and coating a catalyst layer on the opposing second side of the porous substrate, wherein a thickness of the catalyst layer is at least 10 microns. 12. The method of claim 11 wherein the coating of the catalyst layer is carried out after the forming of the surface exchange layer. 13. The method of claim 11 wherein a catalyst layer coating step in the coating of the catalyst layer is carried out prior to a high temperature sintering step in the forming of the surface exchange layer. 14. The method of claim 11 wherein a catalyst layer coating step in the coating of the catalyst layer is carried out prior to a coating step in the forming of the surface exchange layer. 15. The method of claim 11 wherein a catalyst layer coating step in the coating of the catalyst layer is a wash-coating technique.