Methods and systems for hanging structures in downhole environments

What is claimed is: 1. A downhole hanger system comprising: a first structure; a second structure, wherein the first structure is disposed within the second structure; a composite joint arranged on an outer surface of the first structure, wherein the composite joint is formed of a material configured to be fused to both the first structure and the second structure and having a shear strength of at least 2 ksi when the material is fused to the outer surface of the first structure and an inner surface of the second structure; a surface-based high energy source; a high energy delivery device; and a downhole high energy application head, wherein the high energy delivery device operably connects the surface-based high energy source to the downhole high energy application head to apply energy to the composite joint. 2. The downhole hanger system of claim 1 , wherein the first structure is a liner and the second structure is a casing. 3. The downhole hanger system of claim 1 , wherein the material of the composite joint is a self-energizing material that is configured to be triggered to fuse the first structure to the second structure. 4. The downhole hanger system of claim 1 , wherein the surface-based high energy source is one of a millimeter wave (MMW) gyrotron and a kilowatt laser beam source. 5. The downhole hanger system of claim 1 , wherein the high energy delivery device is one of an optical fiber and a wave guide. 6. The downhole hanger system of claim 1 , wherein the downhole high energy application head is configured to be moveable both axially relative to an axis of the first structure and rotationally about said axis. 7. The downhole hanger system of claim 1 , wherein the downhole high energy application head comprises a beam collimate lens and a beam focus lens. 8. The downhole hanger system of claim 1 , wherein the composite joint comprises a plurality of discrete elements distributed equally about the outer surface of the first structure. 9. The downhole hanger system of claim 1 , further comprising a seal arranged on the outer surface of the first structure and at a position closer uphole from the composite joint and configured to form a fluid seal uphole of the fused composite joint. 10. The downhole hanger system of claim 9 , wherein the seal is configured to be fused to the outer surface of the first structure and the inner surface of the second structure by application of high energy. 11. The downhole hanger system of claim 9 , wherein the seal is formed of a material that is a self-energizing material configured to be triggered to fuse the first structure to the second structure and form a fluid seal. 12. A method for hanging a first structure from a second structure in a downhole environment, the method comprising: deploying the first structure within the second structure, wherein the first structure includes a composite joint arranged on an outer surface of the first structure; activating the composite joint to fuse the outer surface of the first structure to the second structure, wherein the composite joint is formed of a material configured to be fused to both the first structure and the second structure and having a shear strength of at least 2 ksi when the material is fused to the outer surface of the first structure and an inner surface of the second structure, wherein activating the composite joint comprises transmitting high energy from a surface-based high energy source, through a high energy delivery device, to a downhole high energy application head to apply the high energy to the material of the composite joint. 13. The method of claim 12 , wherein the material of the composite joint is a self-energizing material that is configured to be triggered to fuse the first structure to the second structure, the method further comprising: performing a triggering operation to activate the composite joint. 14. The method of claim 12 , wherein the surface-based high energy source is one of a millimeter wave (MMW) gyrotron, a kilowatt laser beam source, and an electric current sent by wireline to an electronic-match. 15. The method of claim 12 , wherein the downhole high energy application head is configured to be moveable both axially relative to an axis of the first structure and rotationally about said axis, the method further comprising: controlling movement of the downhole high energy application head to apply the high energy to the material of the composite joint. 16. The method of claim 12 , wherein the composite joint comprises a plurality of discrete elements distributed equally about the outer surface of the first structure. 17. The method of claim 12 , further comprising a seal arranged on the outer surface of the first structure and at a position closer to the Earth's surface than the composite joint and configured to form a fluid seal uphole from the fused composite joint. 18. The method of claim 17 , the method further comprising applying high energy to the seal to fuse to the outer surface of the first structure and the inner surface of the second structure. 19. A method for hanging a first structure from a second structure in a downhole environment, the method comprising: deploying the first structure within the second structure in the downhole environment, wherein the first structure includes a composite joint arranged on an outer surface of the first structure, wherein the material of the composite joint comprises a self-energizing material that is configured to be triggered to fuse the first structure to the second structure; generating a trigger signal when the composite joint is positioned relative to the second structure at a location to hang the first structure from the second structure; receiving the trigger signal at the composite joint when located in the downhole environment; and activating the composite joint, in response to the trigger signal, to fuse the outer surface of the first structure to the second structure, wherein the composite joint is formed of a material configured to be fused to both the first structure and the second structure and having a shear strength of at least 2 ksi when the material is fused to the outer surface of the first structure and an inner surface of the second structure. 20. The method of claim 19 , wherein the trigger signal is transmitted from Earth's surface to the composite joint.