Built-up composite structures with a graded coefficient of thermal expansion for extreme environment applications

What is claimed is: 1. A method for producing an integrated composite interface with a graded coefficient of thermal expansion (CTE) comprising the steps of: identifying a first CTE for a first structural member, wherein the first structural member comprises a ceramic matrix composite chamber; identifying a second CTE for a second structural member, wherein the second structural member comprises a titanium injector; selecting a plurality of layers of graded CTE, wherein each layer has a CTE between the first CTE and the second CTE; building up the layers to form a CTE graded integrated composite employing powder metallurgy processing; and processing the integrated composite to produce a first surface for attachment of the first structural member having the first CTE and to produce a second surface for attachment of the second structural member having the second CTE. 2. The method of claim 1 , wherein the step of selecting a plurality of layers further comprises: selecting an alloy for each of the plurality of layers from a group of alloys comprising, by mass, a first alloy of 53% Fe, 29% Ni, 18% Co, a second alloy of 42% Ni, 0.02% C, 0.4% Mn, 0.15% Si, Balance Fe, a third alloy of 48% Ni, 52% Fe, a fourth alloy of 15% Cr, 5.1% Ni, 0.3% Cb, 3.2% Cu, Balance Fe and a fifth alloy of 52% Ni, 19% Cr, 3% Mo, 5% Cb, 0.9% Ti, 0.5% Al, 18% Fe. 3. The method of claim 1 , wherein the step of building up layers further comprises: building up the layers to provide a graded CTE billet. 4. The method of claim 3 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to provide a strip with orthogonal interfaces between layers. 5. The method of claim 3 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to provide a strip with inclined interfaces between layers. 6. The method of claim 3 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to produce a preliminary shape, expanding the preliminary shape, and rolling the expanded shape to form a near net shape attachment ring. 7. The method of claim 1 , wherein the step of selecting a plurality of layers of graded CTE further comprises: providing interlayers between first and second adjacent layers with a first interlayer having a material composition of about 75% of the material of the first adjacent layer and about 25% of the material of the second adjacent layer, a second interlayer having a material composition of about 50% of the material of the first adjacent layer and about 50% of the material of the second adjacent layer and a third interlayer having a material composition of about 25% of the material of the first adjacent layer and about 75% of the material of the second adjacent layer. 8. A method for producing an integrated composite interface with a graded coefficient of thermal expansion (CTE) comprising the steps of: identifying a first CTE for a first structural member, wherein the first structural member comprises a ceramic matrix composite chamber; identifying a second CTE for a second structural member, wherein the second structural member comprises a titanium injector; using powder metallurgy to produce a CTE graded preform that transitions between the first CTE and the second CTE; consolidating the preform; heat treating the consolidated preform to create a CTE graded integrated composite billet; and forming the billet to provide a first surface for attachment of the first structural member having the first CTE and a second surface of for attachment of the second structural member having the second CTE. 9. The method of claim 8 , wherein the step of consolidating comprises hot isostatic pressing. 10. A method for producing an integrated composite interface with a graded coefficient of thermal expansion (CTE) comprising the steps of: identifying a first CTE for a first structural member, wherein the first structural member comprises a ceramic matrix composite chamber; identifying a second CTE for a second structural member, wherein the second structural member comprises a titanium injector; using powder metallurgy to produce a CTE graded preform in near net shape that transitions between the first CTE and the second CTE; consolidating the preform; heat treating the consolidated preform to create a CTE graded near net shape component; and forming the component to provide a first surface for attachment of the first structural member having the first CTE and a second surface of for attachment of the second structural member having the second CTE. 11. The method of claim 10 , wherein the step of consolidating comprises hot isostatic pressing. 12. A method for producing an integrated composite interface with a graded coefficient of thermal expansion (CTE) comprising the steps of: identifying a first CTE for a first structural member, wherein the first structural member comprises a ceramic matrix composite exhaust nozzle; identifying a second CTE for a second structural member, wherein the second structural member comprises an alloy aircraft engine nozzle attachment flange; selecting a plurality of layers of graded CTE, wherein each layer has a CTE between the first CTE and the second CTE; building up the layers to form a CTE graded integrated composite employing powder metallurgy processing; and processing the integrated composite to produce a first surface for attachment of the first structural member having the first CTE and to produce a second surface for attachment of the second structural member having the second CTE. 13. The method of claim 12 , wherein the step of selecting a plurality of layers further comprises: selecting an alloy for each of the plurality of layers from a group of alloys comprising, by mass, a first alloy of 53% Fe, 29% Ni, 18% Co, a second alloy of 42% Ni, 0.02% C, 0.4% Mn, 0.15% Si, Balance Fe, a third alloy of 48% Ni, 52% Fe, a fourth alloy of 15% Cr, 5.1% Ni, 0.3% Cb, 3.2% Cu, Balance Fe and a fifth alloy of 52% Ni, 19% Cr, 3% Mo, 5% Cb, 0.9% Ti, 0.5% Al, 18% Fe. 14. The method of claim 12 , wherein the step of building up layers further comprises: building up the layers to provide a graded CTE billet. 15. The method of claim 14 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to provide a strip with orthogonal interfaces between layers. 16. The method of claim 14 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to provide a strip with inclined interfaces between layers. 17. The method of claim 14 , wherein the step of the step of processing the integrated composite further comprises: machining the billet to produce a preliminary shape; expanding the preliminary shape; and rolling the expanded shape to form a near net shape attachment ring. 18. The method of claim 12 , wherein the step of selecting a plurality of layers of graded CTE further comprises: providing interlayers between first and second adjacent layers with a first interlayer having a material composition of about 75% of the material of the first adjacent layer and about 25% of the material of the second adjacent layer, a second interlayer having a material composition of about 50% of the material of the first adjacent layer and about 50% of the material of the second adjacent layer and a third interlayer having a material composition of about 25% of the material of the first