In various embodiments, a metallic structure includes first and second clad structures each comprising a protective layer disposed over a steel layer, a joint joining the steel layers of first and second clad structures, and, directly connecting the protective layers of the first and second clad str
In various embodiments, a metallic structure includes first and second clad structures each comprising a protective layer disposed over a steel layer, a joint joining the steel layers of first and second clad structures, and, directly connecting the protective layers of the first and second clad structures, a layer of metal powder disposed in contact with (i) the joint, (ii) the protective layers of the first and second clad structures, and (iii) a portion of at least one of the steel layers proximate the joint.
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1. A metallic structure comprising: first and second clad structures each comprising a protective layer disposed over a steel layer;a joint joining the steel layers of the first and second clad structures; anda layer of unmetaled metal powder disposed in contact with and bonded to (i) the joint, (ii
1. A metallic structure comprising: first and second clad structures each comprising a protective layer disposed over a steel layer;a joint joining the steel layers of the first and second clad structures; anda layer of unmetaled metal powder disposed in contact with and bonded to (i) the joint, (ii) the protective layers of the first and second clad structures, and (iii) a portion of each of the steel layers proximate the joint. 2. The metallic structure of claim 1, wherein the protective layers each comprise at least one of tantalum, niobium, titanium, zirconium, molybdenum, or tungsten. 3. The metallic structure of claim 1, wherein the joint comprises a weld. 4. The metallic structure of claim 3, wherein the weld comprises a butt weld or a lap weld. 5. The metallic structure of claim 1, wherein the protective layers are substantially resistant to at least one of acid or corrosion. 6. The metallic structure of claim 1, wherein, for each of the first and second clad structures, the protective layer is disposed over substantially all of a top surface of the steel layer except for an edge region proximate the joint. 7. The metallic structure of claim 1, wherein, for each of the first and second clad structures, the protective layer is irreversibly attached to the steel layer. 8. The metallic structure of claim 1, wherein the layer of metal powder is substantially free of oxygen. 9. The metallic structure of claim 1, wherein, in each of the first and second clad structures, the protective layer is disposed directly over and in contact with the steel layer. 10. The metallic structure of claim 1, wherein a structural adhesive, a low-temperature brazing material, or a low-temperature solder is disposed between and in direct contact with the protective layer and the steel layer of each of the first and second clad structures. 11. The metallic structure of claim 10, wherein a structural adhesive having a decomposition temperature less than approximately 300° C. is disposed between and in direct contact with the protective layer and the steel layer of each of the first and second clad structures. 12. The metallic structure of claim 10, wherein a low-temperature solder having a melting point less than approximately 400° C. is disposed between and in direct contact with the protective layer and the steel layer of each of the first and second clad structures. 13. The metallic structure of claim 1, wherein the protective layers of the first and second clad structures have thicknesses ranging from approximately 0.005 inch to approximately 0.02 inch. 14. The metallic structure of claim 13, wherein the protective layers of the first and second clad structures have thicknesses ranging from approximately 0.005 inch to approximately 0.01 inch. 15. The metallic structure of claim 1, wherein the layer of metal powder comprises elongated particles having a random crystallographic orientation. 16. The metallic structure of claim 15, wherein the particles are elongated in a direction substantially parallel to a top surface of the first clad structure. 17. The metallic structure of claim 15, wherein the particles have an aspect ratio ranging from 2 to 6. 18. The metallic structure of claim 17, wherein the particles have an aspect ratio ranging from 2 to 3. 19. The metallic structure of claim 1, wherein the layer of metal powder comprises non-directional equiaxed grains having a random crystallographic orientation. 20. The metallic structure of claim 1, wherein the layer of metal powder has a density greater than approximately 95%. 21. The metallic structure of claim 20, wherein the layer of metal powder has a density greater than approximately 97.5%. 22. The metallic structure of claim 1, wherein the steel layer of each of the first and second clad structures comprises stainless steel. 23. The metallic structure of claim 1, wherein neither of the first or second clad structures comprises a heat affected zone proximate the joint. 24. The metallic structure of claim 1, wherein at least one of the protective layer of the first clad structure or the protective layer of the second clad structure comprises a second layer of metal powder. 25. The metallic structure of claim 24, wherein the second layer of metal powder is unmelted. 26. The metallic structure of claim 24, wherein the second layer of metal powder comprises elongated particles having a random crystallographic orientation. 27. The metallic structure of claim 26, wherein the particles are elongated in a direction substantially parallel to a top surface of at least one of the first clad structure or the second clad structure.
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