Optical fiber for light amplification having a core with low bend loss and end features with high bend loss and related method

What is claimed is: 1. An apparatus comprising: an optical fiber configured to transport an optical signal, the optical fiber comprising: a core configured to receive and amplify the optical signal; end features optically coupled to the core at opposite ends of the core, wherein the core has a lower bend loss than the end features; and a cladding surrounding the core and the end features; wherein the optical fiber is configured to confine optical power of a fundamental mode in the core; wherein the optical fiber is also configured to allow optical power of one or more higher-order modes to leak from the core into the end features; and wherein the optical fiber is bent to allow the optical power in the end features to leak from the end features into the cladding, wherein a bend radius of the optical fiber is selected in order to strip the optical power in the end features while allowing the optical fiber to guide the optical power of the fundamental mode in the core. 2. The apparatus of claim 1 , wherein a refractive index offset between material in the core and material in the end features is selected to prevent a direct resonance between the fundamental mode in the core and any mode in one or more of the end features. 3. The apparatus of claim 1 , wherein: the optical fiber has a slow-axis direction and a fast-axis direction; the optical fiber is configured to guide the optical power of the fundamental mode in the fast-axis direction; and the optical fiber is configured to allow the optical power of the one or more higher-order modes to leak out of the core through slow-axis edges of the core. 4. The apparatus of claim 1 , wherein: the core is elongated; each of the end features is elongated; and each of the end features has a dimension parallel to a fast-axis dimension of the core that is larger than the fast-axis dimension of the core. 5. The apparatus of claim 4 , wherein: the core is rectangular; and each of the end features is rectangular or elliptical. 6. The apparatus of claim 1 , wherein: the core comprises at least one material and is doped with active lasing ions; and each of the end features comprises the at least one material and is not doped with any active lasing ions, each of the end features contacting the core. 7. The apparatus of claim 4 , wherein an aspect ratio of the core, determined as a slow-axis dimension to fast-axis dimension ratio, is at least 10:1. 8. A method comprising: injecting an optical signal into an optical fiber; confining optical power of a fundamental mode in a core of the optical fiber, wherein the core is configured to receive and amplify the optical signal; and allowing optical power of one or more higher-order modes to leak from the core into end features, wherein the end features are optically coupled to the core at opposite ends of the core, and wherein the core has a lower bend loss than the end features, wherein the optical fiber is bent to allow the optical power in the end features to leak from the end features into a cladding surrounding the core and the end features, wherein a bend radius of the optical fiber is selected in order to strip the optical power in the end features while allowing the optical fiber to guide the optical power of the fundamental mode in the core. 9. The method of claim 8 , further comprising: selecting a refractive index offset between material in the core and material in the end features to prevent a direct resonance between the fundamental mode in the core and any mode in one or more of the end features. 10. The method of claim 8 , wherein: the optical fiber has a slow-axis direction and a fast-axis direction; the optical fiber guides the optical power of the fundamental mode in the fast-axis direction; and the optical fiber allows the optical power of the one or more higher-order modes to leak out of the core through slow-axis edges of the core. 11. The method of claim 8 , wherein: the core is elongated; each of the end features is elongated; and each of the end features has a dimension parallel to a fast-axis dimension of the core that is larger than the fast-axis dimension of the core. 12. The method of claim 11 , wherein: the core is rectangular; and each of the end features is rectangular or elliptical. 13. The method of claim 8 , wherein: the core comprises at least one material and is doped with active lasing ions; and each of the end features comprises the at least one material and is not doped with any active lasing ions, each of the end features contacting the core. 14. The method of claim 11 , wherein an aspect ratio of the core, determined as a slow-axis dimension to fast-axis dimension ratio, is at least 10:1. 15. A method comprising: obtaining an optical fiber comprising: a core configured to receive and amplify an optical signal; end features optically coupled to the core at opposite ends of the core, wherein the core has a lower bend loss than the end features; and a cladding surrounding the core and the end features; and selecting a bend radius of the optical fiber in order to strip optical power, including optical power of one or more higher-order modes, from the end features while allowing the optical fiber to guide optical power of a fundamental mode in the core. 16. The method of claim 15 , further comprising: selecting a refractive index offset between material in the core and material in the end features in order to at least one of: prevent a direct resonance between the fundamental mode in the core and any mode in one or more of the end features; and provide approximate resonance between one or more higher-order modes in the core and the one or more higher-order modes in the end features. 17. The method of claim 15 , wherein: the optical fiber has a slow-axis direction and a fast-axis direction; the optical fiber is configured to guide the optical power of the fundamental mode in the fast-axis direction; and the optical fiber is configured to allow the optical power of the one or more higher-order modes to leak out of the core through slow-axis edges of the core. 18. The method of claim 15 , wherein: the core is elongated; each of the end features is elongated; and each of the end features has a dimension parallel to a fast-axis dimension of the core that is larger than the fast-axis dimension of the core. 19. The method of claim 15 , wherein: the core comprises at least one material and is doped with active lasing ions; and each of the end features comprises the at least one material and is not doped with any active lasing ions, each of the end features contacting the core. 20. The method of claim 18 , wherein: the core is rectangular; and each of the end features is rectangular or elliptical.