Thermal management for high-power optical fibers

What is claimed is: 1. A method comprising: obtaining a substrate comprising at least one exposed substantially planar metal surface; electro-depositing metal onto the at least one exposed substantially planar metal surface of the substrate and around at least a portion of an optical fiber to secure the optical fiber to the substrate and encase at least the portion of the optical fiber, the optical fiber comprising a cladding surrounding a core along a length of the optical fiber except at an end portion of the optical fiber, the electro-deposited metal filling multiple areas between the optical fiber and the substantially planar metal surface, the electro-deposited metal comprising an end portion that encases the end portion of the optical fiber that is not surrounded by the cladding, the optical fiber having multiple points of contact with the substantially planar metal surface, the optical fiber forming at least one coil on the substantially planar metal surface, the at least one coil comprising at least one full loop in contact with the substantially planar metal surface; and providing an optical film over a surface formed by the end portion of the optical fiber and the end portion of the electro-deposited metal; wherein the substrate and the electro-deposited metal are configured to remove heat from the optical fiber. 2. The method of claim 1 , further comprising: electro-depositing metal around a sacrificial material; and removing the sacrificial material to form at least one cooling channel through the electro-deposited metal, the at least one cooling channel configured to carry a cooling fluid. 3. The method of claim 1 , wherein: the cladding initially surrounds the core along the length of the optical fiber including at the end portion of the optical fiber; and the method further comprises removing a portion of the cladding at the end portion of the optical fiber. 4. The method of claim 1 , wherein the substrate and the electro-deposited metal collectively have a thermal mass that exceeds a thermal mass of the optical fiber by at least about three orders of magnitude. 5. The method of claim 1 , further comprising: faceting the substrate and the electro-deposited metal at an input of the optical fiber and at an output of the optical fiber. 6. The method of claim 1 , wherein electro-depositing the metal comprises electro-depositing the metal at room temperature. 7. The method of claim 1 , further comprising: forming a port so that a portion of the optical fiber remains exposed through the electro-deposited metal. 8. The method of claim 1 , wherein the optical fiber follows an in-plane coiled path in one direction before reversing a direction of travel and then following an in-plane coiled path in another direction. 9. The method of claim 1 , wherein electro-depositing the metal comprises fully encasing the optical fiber in the electro-deposited metal. 10. An apparatus comprising: a substrate having a substantially planar surface; an optical fiber having multiple points of contact with the substantially planar surface of the substrate, the optical fiber forming at least one coil on the substantially planar surface, the at least one coil comprising at least one full loop in contact with the substantially planar surface, the optical fiber comprising a cladding surrounding a core along a length of the optical fiber except at an end portion of the optical fiber; electro-deposited metal in contact with the substantially planar surface and encasing at least a portion of the optical fiber, the electro-deposited metal filling multiple areas between the optical fiber and the substantially planar surface, the electro-deposited metal comprising an end portion that encases the end portion of the optical fiber that is not surrounded by the cladding; and an optical film disposed over a surface formed by the end portion of the optical fiber and the end portion of the electro-deposited metal; wherein the substrate and the electro-deposited metal are configured to remove heat from the optical fiber. 11. The apparatus of claim 10 , wherein: the optical fiber comprises multiple segments joined at a splice or fused fiber coupler; and the substrate and the electro-deposited metal surround the splice or fused fiber coupler. 12. The apparatus of claim 10 , wherein: the substrate comprises a second core and a metal deposited on the second core; and the electro-deposited metal is located on the metal of the substrate. 13. The apparatus of claim 10 , further comprising: a material surrounding at least part of the optical fiber, the electro-deposited metal located around at least a portion of the material; wherein the material comprises a second metal that is softer than the electro-deposited metal. 14. The apparatus of claim 10 , wherein the surface formed by the end portion of the optical fiber and the end portion of the electro-deposited metal is at an angle relative to the optical fiber, the angle selected such that reflected signal light is able to penetrate into the cladding. 15. The apparatus of claim 10 , further comprising: at least one cooling channel through the electro-deposited metal, the at least one cooling channel configured to carry a cooling fluid. 16. The apparatus of claim 10 , further comprising: a port through the electro-deposited metal, the port exposing a portion of the optical fiber to an exterior environment. 17. The apparatus of claim 10 , wherein the substrate and the electro-deposited metal collectively have a thermal mass that exceeds a thermal mass of the optical fiber by at least about three orders of magnitude. 18. The apparatus of claim 10 , wherein: a first one of the multiple filled areas between the optical fiber and the substrate is on a first side of a first one of the multiple points of contact; and a second one of the multiple filled areas between the optical fiber and the substrate is on a second side of the first point of contact. 19. A system comprising: a laser configured to generate optical signals; and an apparatus configured to transport the optical signals, the apparatus comprising: a substrate having a substantially planar surface; an optical fiber configured to transport the optical signals, the optical fiber having multiple points of contact with the substantially planar surface of the substrate, the optical fiber forming at least one coil on the substantially planar surface, the at least one coil comprising at least one full loop in contact with the substantially planar surface, the optical fiber comprising a cladding surrounding a core along a length of the optical fiber except at an end portion of the optical fiber; electro-deposited metal in contact with the substantially planar surface and encasing at least a portion of the optical fiber, the electro-deposited metal filling multiple areas between the optical fiber and the substantially planar surface, the electro-deposited metal comprising an end portion that encases the end portion of the optical fiber that is not surrounded by the cladding; and an optical film disposed over a surface formed by the end portion of the optical fiber and the end portion of the electro-deposited metal; wherein the substrate and the electro-deposited metal are configured to remove heat from the optical fiber. 20. The system of claim 19 , further comprising: a heat transfer unit thermally coupled to the substrate and the electro-deposited metal, the heat transfer unit configured to remove heat from the