Coupling between nanostructures and optical fibers

What is claimed is: 1. A method to enhance optical coupling between at least one nanostructure and an optical fiber, the method comprising: suspending nanostructures in a fluid to form a nanostructure suspension, the nanostructures including the at least one nanostructure and a polarizable material; inserting a first end of the optical fiber into the nanostructure suspension; coupling a light source to a second end of the optical fiber; directing light from the light source into the second end of the optical fiber to induce an optical gradient force within the nanostructure suspension proximate to the first end of the optical fiber such that the at least one nanostructure is aligned by the induced optical gradient force at the first end of the optical fiber; and affixing the at least one nanostructure to the first end of the optical fiber to form a nanostructure-optical fiber assembly, wherein affixing the at least one nanostructure to the first end of the optical fiber further comprises: directing a pulsed ultraviolet laser light through the optical fiber causing a portion of a photopolymerizable coating of the at least one nanostructure to polymerize near the first end of the optical fiber, wherein polymerizing the portion of the optical fiber includes two-photon polymerization; forming a chemical bond between the at least one nanostructure and the first end of the optical fiber to form the nanostructure-optical fiber assembly, wherein forming the chemical bond includes forming the chemical bond between a functional group supported by the at least one nanostructure and the first end of the optical fiber; treating tips of the nanostructures with a fluidic polymer prior to suspension in the fluid; and solidifying the polymer at the tip of the at least one nanostructure in contact with the first end of the optical fiber. 2. The method of claim 1 , wherein suspending the nanostructures in the fluid comprises: suspending the nanostructures in a microfluidic suspension fluid contained in a fluidic chamber, wherein the nanostructures include one or more of a semiconductor, an oxide, and a metal. 3. The method of claim 1 , further comprising: forming a taper of the optical fiber near the first end employing one or more of chemical etching, mechanical polishing, and drawing a region of the optical fiber through a heating zone. 4. The method of claim 1 , wherein the light source is one of an infrared laser and a visible laser. 5. The method of claim 1 , wherein inserting the first end of the optical fiber into the nanostructure suspension comprises one or more of: translating the first end of the optical fiber within the fluid; and directing the nanostructures to flow near the first end of the optical fiber through one or more flow channels within a fluidic chamber comprising the fluid. 6. The method of claim 1 , further comprising: inducing the optical gradient force such that the at least one nanostructure is attracted to the first end of the optical fiber and is aligned with a long axis of the at least one nanostructure parallel to a long axis of the optical fiber in response to the optical gradient force. 7. The method of claim 1 , further comprising: forming the nanostructures by one of a solution employing chemical synthesis and via epitaxial growth on a substrate employing a vapor-liquid-solid (VLS) method, wherein the nanostructures are one of nanowires and single crystal nanostructures. 8. The method of claim 1 , wherein the nanostructures have a root mean square (RMS) surface roughness in a range from about 0.1 to about 0.2 nanometers. 9. The method of claim 1 , further comprising: initially dispersing the nanostructures into a photopolymerizable coating prior to suspension within the fluid, such that the photopolymerizable coating coats the nanostructures. 10. The method of claim 1 , further comprising: removing the nanostructure-optical fiber assembly from the fluid; and employing the nanostructure-optical fiber assembly to optically couple the at least one affixed nanostructure and the optical fiber to a target device. 11. The method of claim 10 , further comprising: positioning the at least one affixed nanostructure next to a second nanostructure on the target device such that a portion of the at least one affixed nanostructure and a portion of the second nanostructure overlap over an interaction length and the pulsed ultraviolet laser light is transferred between the second nanostructure and the at least one affixed nanostructure over the overlapping interaction length; and adjusting the interaction length to improve transfer of the pulsed ultraviolet laser light between the second nanostructure and the at least one affixed nanostructure. 12. The method of claim 1 , further comprising: providing fluidic chambers, wherein each fluidic chamber contains one or more of the nanostructures of different sizes and the nanostructures composed from a different material to enable selection of the nanostructures for a selected optical fiber size. 13. A method to fabricate a nanostructure-optical fiber assembly coupled with a target device, the method comprising: suspending nanostructures in a suspension fluid to form a nanostructure suspension; inserting a first end of an optical fiber into the nanostructure suspension; coupling a light source with a second end of the optical fiber; directing light from the light source into the second end of the optical fiber to induce an optical gradient force at the first end of the optical fiber such that at least one nanostructure is aligned with the first end of the optical fiber due to the optical gradient force; affixing the at least one aligned nanostructure to the first end of the optical fiber to form a nanostructure-optical fiber assembly; removing the nanostructure-optical fiber assembly from the nanostructure suspension; optically coupling the nanostructure-optical fiber assembly to the target device; and inserting the at least one affixed nanostructure to the optical fiber within a registration groove of the target device to fabricate the nanostructure-optical fiber assembly coupled with the target device. 14. The method of claim 13 , wherein the target device is an integrated nanophotonic component and includes at least a second nanostructure affixed on a substrate. 15. The method of claim 13 , wherein affixing the at least one nanostructure to the first end of the optical fiber comprises: directing a pulsed laser light through the optical fiber to illuminate the at least one nanostructure; and solidifying a polymer applied near a tip of the at least one nanostructure in contact with the first end of the optical fiber employing two-photon polymerization. 16. The method of claim 13 , further comprising: positioning the at least one affixed nanostructure next to a second nanostructure on the target device such that a portion of the at least one affixed nanostructure and a portion of the second nanostructure overlap over an interaction length; and adjusting the interaction length to improve transfer of light between the second nanostructure and the at least one affixed nanostructure.