Josephson junction readout for graphene-based single photon detector

What is claimed is: 1. A photon detector comprising: a graphene sheet; a waveguide adjacent the graphene sheet, the waveguide configured to guide infrared electromagnetic waves in a mode having an evanescent field coupled to the graphene sheet, to produce an increase in a temperature of the graphene sheet when a photon of the evanescent field is absorbed by the graphene sheet; a Josephson junction on the graphene sheet, the Josephson junction having a gap coupled to electrons of the graphene sheet; and a circuit connected to two contacts of the Josephson junction, the circuit configured to detect a decrease in a critical current of the Josephson junction, the decrease corresponding to the increase in the temperature of the graphene sheet. 2. The photon detector of claim 1 , wherein the graphene sheet has an electron mobility of more than 100,000 cm 2 /V/s. 3. The photon detector of claim 1 , wherein the graphene sheet has an electron mobility of about 1,000 cm 2 /V/s. 4. The photon detector of claim 1 , wherein the graphene sheet substantially has the shape of a rectangle, the rectangle having a length and a width, the length being greater than or equal to the width. 5. The photon detector of claim 4 , wherein the length of the rectangle is less than 20 microns. 6. The photon detector of claim 4 , wherein the product of the length of the rectangle and the width of the rectangle is less than 1000 square microns. 7. The photon detector of claim 4 , wherein the waveguide has a curved section, the curved section having a radius of curvature less than the length of the rectangle, the curved section resulting in a change of direction of the waveguide of at least 45 degrees. 8. The photon detector of claim 1 , wherein the waveguide comprises a reflector. 9. The photon detector of claim 1 wherein the waveguide is on a substantially flat substrate, in a layer on a surface of the substrate, the layer having a thickness greater than 10 nanometers and less than 2 microns. 10. The photon detector of claim 1 , comprising a first layer of hexagonal boron nitride immediately adjacent a first surface of the graphene sheet, and a second layer of hexagonal boron nitride immediately adjacent a second surface of the graphene sheet. 11. The photon detector of claim 10 , wherein each of the first layer of hexagonal boron nitride and the second layer of hexagonal boron nitride has a thickness greater than 4 nm and less than 40 nm. 12. The photon detector of claim 1 , wherein the circuit comprises a current source connected to the two contacts of the Josephson junction and configured to drive a constant bias current through the Josephson junction. 13. The photon detector of claim 12 , further comprising an amplifier connected to the two contacts of the Josephson junction. 14. The photon detector of claim 13 , further comprising a matching circuit connected between the two contacts and the amplifier. 15. The photon detector of claim 14 , further comprising a pulse detector connected to the amplifier, the pulse detector comprising a voltage reference and a comparator configured to compare the output of the amplifier to the output of the voltage reference. 16. The detector of claim 1 , wherein the graphene sheet consists of a single atomic layer of graphene. 17. The detector of claim 1 , wherein the graphene sheet comprises two atomic layers of graphene. 18. The photon detector of claim 1 , further comprising a refrigerator configured to cool the graphene sheet to a temperature below 4 K. 19. The photon detector of claim 18 , wherein the refrigerator is a pulse tube refrigerator. 20. The photon detector of claim 18 , wherein the refrigerator is a Gifford-McMahon cooler.