Apparatus and methods for single photon sources

The invention claimed is: 1. A single-photon source comprising: a first resonator to receive pump photons from a photon source and to generate a signal photon from the pump photons; a switch, optically coupled to the first resonator, to prevent transmission, in response to a first signal, and to allow transmission, in response to a second signal, of subsequent pump photons from the photon source to the first resonator; and a second resonator, optically coupled to the first resonator, to receive the signal photon out of the first resonator and, in response to the second signal, to couple the signal photon out of the first resonator. 2. The single-photon source of claim 1 , wherein the first resonator comprises a ring resonator. 3. The single-photon source of claim 1 , wherein the first resonator is configured to resonate at a first frequency and the second resonator is configured to resonate a second frequency different than the first frequency. 4. The single-photon source of claim 1 , wherein the photon source comprises a laser source, in optical communication with the switch, to provide the pump photons. 5. The single-photon source of claim 1 , wherein the second resonator is configured to resonate at a frequency of the signal photon in response to the second signal so as to couple the signal photon out of the second resonator. 6. The single-photon source of claim 1 , wherein the second resonator is fabricated in a semiconductor substrate. 7. The single-photon source of claim 1 , further comprising: a third resonator, optically coupled between the switch and the second resonator, to couple the pump photons from the photon source into the first resonator. 8. The single-photon source of claim 1 , further comprising: a detector, operably coupled to the first resonator, to detect an idler photon generated from the pump photons and to generate the control signal in response to detecting the idler photon. 9. The single-photon source of claim 1 , further comprising: a clock signal generator, operably coupled to the second resonator, to generate the second signal. 10. A method of delivering single photons, the method comprising: coupling pump photons at a pump frequency from a photon source to a resonator; generating a signal photon at a signal frequency different than the pump frequency in the resonator from the pump photons; preventing transmission of subsequent pump photons from the photon source to the resonator while the signal photon is in the resonator; and coupling the signal photon out of the resonator in response to a clock signal. 11. The method of claim 10 , wherein coupling the pump photons from the photon source to the resonator comprises: receiving the pump photons from the photon source using a pump resonator resonating at the pump frequency; and coupling the pump photons from the resonator to an additional resonator. 12. The method of claim 10 , wherein generating the signal photon occurs via a degenerate four wave mixing process. 13. The method of claim 10 , wherein preventing transmission of subsequent pump photons from the photon source to the resonator comprises: detecting an idler photon created from the pump photons; and controlling a resonance frequency of the resonator based on detection of the idler photon. 14. The method of claim 13 , wherein coupling the signal photon out of the resonator comprises changing the resonance frequency of the resonator to the signal frequency in response to the clock signal. 15. A single-photon source comprising: a storage resonator to receive pump photons from a photon source at a pump frequency ω P and to generate a signal photon at a signal frequency ω s and an idler photon at an idler frequency ω i from the pump photons, wherein the signal frequency ω s is different than the idler frequency ω i ; a detector, operably coupled to the storage resonator, to detect the idler photon and to generate a control signal in response to detection of the idler photon; a pump gate, operably coupled to the detector and optically coupled to the storage resonator, to prevent transmission, in response to the control signal, and to allow transmission, in response to a clock signal, of subsequent pump photons from the photon source to the storage resonator; and a signal gate, optically coupled to the storage resonator, to receive the signal photon out of the storage resonator and, in response to the clock signal, to couple the signal photon into an output coupler. 16. The single-photon source of claim 15 , wherein the storage resonator is a ring resonator. 17. The single-photon source of claim 15 , wherein the storage resonator is configured to resonate at the signal frequency ω s . 18. The single-photon source of claim 15 , wherein the pump gate comprises: a pump ring resonator, optically coupled to the storage resonator, to couple the pump photons from the photon source into the storage resonator, wherein the pump ring resonator is configured to resonate at the pump frequency ω P . 19. The single-photon source of claim 15 , further comprising: a detector gate, optically coupled between the storage resonator and the detector, to couple the idler photon from the storage resonator to the detector and block the signal photon from entering the detector. 20. The single-photon source of claim 19 , further comprising: a feedback link operably coupled to the detector and the detector gate, wherein the detector is further configured to transmit the control signal to the detector gate, via the feedback link, to turn off the detector gate.