Fiber optical superconducting nanowire single photon detector

We claim: 1. A superconducting nanowire detector device, comprising: a section of input optical fiber for inputting an optical signal to be detected; and an optical cavity constructed at an end of said optical fiber, said cavity comprising serially: a first reflective element; a superconductive nanowire meander structure, which, when cooled to its operating temperature, is adapted to provide a detector output signal responsive to the incidence of photons; and a high reflectivity mirror disposed at the end of said cavity remote from said optical fiber, wherein the reflectivities of said first reflective element and of said high reflectivity mirror are such that coupling close to critical is obtained for light incident on said cavity from said input fiber. 2. A superconducting nanowire detector device according to claim 1 , wherein coupling of light incident from said input fiber into said cavity is sufficiently close to critical coupling that said light has a likelihood of at least 80% that it will be absorbed in said cavity. 3. A superconducting nanowire detector device according to claim 1 , wherein said first reflective element is a Bragg Grating Mirror formed within said optical fiber. 4. A superconducting nanowire detector device according to claim 1 , wherein said first reflective element is a partially transmitting mirror, formed on the end of said optical fiber. 5. A superconducting nanowire detector device according to claim 1 , wherein said high reflectivity mirror is an essentially fully reflective metallic mirror. 6. A superconducting nanowire detector device according to claim 1 , wherein said high reflectivity mirror is an essentially fully reflective dielectric mirror. 7. A superconducting nanowire detector device according to claim 1 , wherein said cavity is constructed to have a Q of at least 10. 8. A superconducting nanowire detector device according to claim 1 , wherein said cavity is constructed to have a Q of at least 100. 9. A superconducting nanowire detector device according to claim 1 , wherein said superconductive nanowire meander structure is formed directly on the end of said input fiber and in a location such that it is essentially aligned with the core of said fiber. 10. A superconducting nanowire detector device according to claim 1 , wherein at least said superconductive nanowire meander structure and said high reflectivity mirror are formed using planar deposition and lithographical processes. 11. A superconducting nanowire detector device, comprising: a section of input optical fiber for inputting an optical signal to be detected; and a superconductive nanowire detector structure, which, when cooled to its operating temperature, is adapted to provide a detector output signal responsive to the incidence of photons from said input fiber, wherein said superconductive nanowire detector structure is formed within an optical cavity disposed directly at an end of said input fiber in a location such that it is aligned with the core of said fiber. 12. A superconducting nanowire detector device according to claim 11 , wherein said superconductive nanowire detector structure is formed using planar deposition and lithographical processes. 13. A superconducting nanowire detector device according to claim 11 , wherein said optical cavity comprises a first reflective element at the optical fiber end of said cavity and a high reflectivity mirror at an end of said cavity remote from said optical fiber. 14. A superconducting nanowire detector device according to claim 13 , wherein said first reflective element is either of a Bragg Grating Mirror formed within said optical fiber, or a partially transmitting metallic mirror, formed on the end of said optical fiber. 15. A method of constructing a superconducting nanowire detector device, comprising: providing a section of input optical fiber for inputting an optical signal to be detected; and forming by a process performed directly on an end of said fiber, in a location that is axially aligned with the core of said fiber, a superconductive nanowire detector, which, when cooled to its operating temperature, provides a detector output signal responsive to the input of photons through said input fiber. 16. A method according to claim 15 , further comprising the step of providing an optical cavity on the end of said fiber, wherein said superconductive nanowire detector is disposed within said optical cavity. 17. A method according to claim 16 , wherein said optical cavity comprises (a) either a Bragg Grating Mirror formed in the end section of said optical fiber or a partially transmitting mirror formed on the end of said optical fiber, as a first cavity mirror, and (b) a high reflectivity mirror as a second cavity mirror. 18. A method according to claim 16 , wherein said forming of said superconductive nanowire detector on the end of said fiber is operative to optimize the coupling of said optical signal to said superconductive nanowire detector. 19. A method according to claim 18 , wherein said optimizing of said coupling provides increased coupling of said optical signal to said superconductive nanowire detector compared to a superconductive nanowire detector disposed discretely on the end of said input fiber. 20. A method according to claim 18 , wherein said optimizing of said coupling provides increased coupling of said optical signal to said superconductive nanowire detector compared to a superconductive nanowire detector not disposed within said optical cavity. 21. A method according to claim 15 , wherein said wherein said superconductive nanowire detector structure is formed using planar deposition and lithographical processes.