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A catalytic oxidation module for a catalytic combustor of a gas turbine engine is provided. The catalytic oxidation module comprises a plurality of spaced apart catalytic elements for receiving a fuel-air mixture over a surface of the catalytic elements. The plurality of catalytic elements includes

A catalytic oxidation module for a catalytic combustor of a gas turbine engine is provided. The catalytic oxidation module comprises a plurality of spaced apart catalytic elements for receiving a fuel-air mixture over a surface of the catalytic elements. The plurality of catalytic elements includes at least one primary catalytic element comprising a monometallic catalyst and secondary catalytic elements adjacent the primary catalytic element comprising a multi-component catalyst. Ignition of the monometallic catalyst of the primary catalytic element is effective to rapidly increase a temperature within the catalytic oxidation module to a degree sufficient to ignite the multi-component catalyst.

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1. A catalytic oxidation module comprising: a plurality of spaced apart catalytic elements oriented along a flow axis for receiving a fuel mixture over a surface thereof and for discharging a partially oxidized fuel mixture at respective ends thereof, the plurality of spaced apart catalytic elements

1. A catalytic oxidation module comprising: a plurality of spaced apart catalytic elements oriented along a flow axis for receiving a fuel mixture over a surface thereof and for discharging a partially oxidized fuel mixture at respective ends thereof, the plurality of spaced apart catalytic elements comprising:at least one primary catalytic element comprising a monometallic catalyst deposited on at least a portion of a surface thereof; andsecondary catalytic elements disposed adjacent the at least one primary catalytic element at a plane transverse to the flow axis, the plane located upstream from a downstream end of the at least one primary catalytic element, the secondary catalytic elements comprising a multi-component catalyst deposited on at least a portion of a surface thereof;wherein ignition of the monometallic catalyst on the at least one primary catalytic element at a temperature initially insufficient to ignite the multi-component catalyst is effective to increase a temperature of the fuel mixture and a surface temperature of the at least one primary catalytic element and the secondary catalytic elements to a degree sufficient to ignite the multi-component catalyst. 2. The catalytic oxidation module of claim 1, wherein the monometallic catalyst comprises a single catalyst selected from the group consisting of a precious metal, a Group VII noble metal, a Group VIII noble metal, a transition metal, a lanthanide metal, an actinide metal, a base metal, a metal salt, and a metal oxide. 3. The catalytic oxidation module of claim 1, wherein the monometallic catalyst comprises a light off temperature of between 300° C. and 400° C. when methane or natural gas is present in the fuel mixture. 4. The catalytic oxidation module of claim 1, wherein the multi-component catalyst comprises a bi-metallic catalyst. 5. The catalytic oxidation module of claim 4, wherein the multi-component catalyst comprises at least two catalysts selected from the group consisting of a precious metal, a Group VII noble metal, a Group VIII noble metal, a transition metal, a lanthanide metal, an actinide metal, a base metal, a metal salt, a single metal oxide, and a multi-metal oxide. 6. The catalytic oxidation module of claim 4, wherein the multi-component catalyst comprises a Pt—Pd catalyst. 7. The catalytic oxidation module of claim 1, wherein the multi-component catalyst comprises at least three catalysts selected from the group consisting of a precious metal, a Group VII noble metal, a Group VIII noble metal, a transition metal, a lanthanide metal, an actinide metal, a base metal, a metal salt, a single metal oxide, and a multi-metal oxide. 8. The catalytic oxidation module of claim 7, wherein the multi-component catalyst comprises at least three metals selected from the group consisting of platinum, palladium, ruthenium, and rhodium. 9. The catalytic oxidation module of claim 1, wherein the multi-component catalyst comprises a light off temperature of greater than 400° C. 10. The catalytic oxidation module of claim 1, wherein a surface area ratio of the monometallic catalyst to the multi-component catalyst in the catalytic oxidation module is from 1:10 to 1:1000. 11. The catalytic oxidation module of claim 1, wherein the plurality of catalytic elements comprises a plurality of tubular elements, wherein the at least one primary catalytic element consists essentially of the monometallic catalyst, and wherein the at least one primary catalytic element is surrounded by secondary catalytic elements consisting essentially of the multi-component catalyst. 12. The catalytic oxidation module of claim 1, wherein the at least one primary catalytic element and a plurality of the secondary catalytic elements comprise a segment of the monometallic catalyst at a front end thereof. 13. The catalytic oxidation module of claim 1, wherein the at least one primary catalytic element and the secondary catalytic elements comprise corrugated panels, and wherein a surface area ratio of the monometallic catalyst to the multi-component catalyst on the corrugated panels is from 1:10 to 1:1000. 14. The catalytic oxidation module of claim 1, wherein the monometallic catalyst is configured to start an exothermic catalytic reaction in the catalytic oxidation module at a temperature between 300° C. and 400° C. 15. The catalytic oxidation module of claim 1, wherein the at least one primary catalytic element comprises a segment of the monometallic catalyst and a downstream segment comprising a multi-component catalyst, wherein ignition of the monometallic catalyst at a temperature initially insufficient to ignite the multi-component catalyst is effective to increase a temperature of the fuel mixture and a surface temperature of the at least one primary catalytic element to a degree sufficient to ignite the multi-component catalyst. 16. A catalytic oxidation module comprising: a plurality of spaced apart catalytic elements for receiving a fuel mixture over a surface thereof and for discharging a partially oxidized fuel mixture at respective ends thereof, the plurality of catalytic elements comprising:at least one primary catalytic element comprising a monometallic catalyst deposited on at least a portion of a surface thereof; anda plurality of secondary catalytic elements surrounding the at least one primary catalytic element, each of the secondary catalytic elements comprising a multi-component catalyst deposited on at least a portion of a surface thereof;wherein ignition of the monometallic catalyst on the at least one primary catalytic element at a temperature initially insufficient to ignite the multi-component catalyst is effective to increase a temperature of the fuel mixture and a surface temperature of the at least one primary catalytic element and the plurality of secondary catalytic elements to a degree sufficient to ignite the multi-component catalyst. 17. The catalytic combustor of claim 16, wherein the monometallic catalyst has a light off temperature of between 300° C. and 400° C. when methane or natural gas is present in the fuel mixture, and wherein the multi-component catalyst has a light off temperature of greater than 400° C. 18. A gas turbine engine comprising the catalytic combustor of claim 16. 19. A method for operating a catalytic combustor comprising: providing a plurality of catalytic elements in a catalytic oxidation module, the plurality of catalytic elements comprising at least one primary catalytic element comprising a monometallic catalyst and a plurality of secondary catalytic elements surrounding the at least one primary catalytic element comprising a multi-component catalyst;igniting the monometallic catalyst, but not the multi-component catalyst, by flowing a fuel-air mixture over the plurality of catalytic elements; andigniting the multi-component catalyst after said igniting of the monometallic catalyst, wherein ignition of the monometallic catalyst is effective to increase a surface temperature of the at least one primary catalytic element, and, via heat transfer, is effective to increase a temperature of fuel-air mixture in the catalytic oxidation module and a surface temperature of the plurality of surrounding secondary catalytic elements to a degree sufficient to ignite the multi-component catalyst. 20. The method of claim 19, wherein the monometallic catalyst starts an exothermic catalytic reaction in the catalytic oxidation module at a temperature between 300° C. and 400° C., and wherein upon ignition of the monometallic catalyst and efficient heat transfer within the catalytic oxidation module, a chain ignition of the multi-component catalyst starts at a temperature above 400° C.