Photonic quantum memory with time-bin entangled photon storage

What is claimed is: 1. A photonic quantum memory, comprising: a polarization-to-time-bin entanglement conversion (P2T) module configured to receive a polarization-entangled photon pair and to generate a time-bin entangled photon pair with a first polarization orientation; a storage configured to: store the time-bin entangled photon pair with the first polarization orientation, and convert the time-bin entangled photon pair with the first polarization orientation to a time-bin entangled photon pair with a second polarization orientation; wherein the storage comprises a linear race track photonic memory with: an entrance fiber optic path; an exit fiber optic path; a first controllable mirror coupled to the entrance fiber optic path; a second controllable mirror coupled to the exit fiber optic path; and a storage fiber optic path that couples the first controllable mirror and the second controllable mirror; and a time-bin-to-polarization entanglement conversion (T2P) module configured to receive the time-bin entangled photon pair with the second polarization orientation and to re-generate the polarization-entangled photon pair with the first polarization orientation. 2. The photonic quantum memory of claim 1 , wherein the storage further comprises: a polarizing beam splitter (PBS) configured to receive a photon of the time-bin entangled photon pair with the first polarization orientation from the P2T module and to direct the photon onto the entrance fiber optic path. 3. The photonic quantum memory of claim 2 , wherein the PBS is further configured to receive the photon from the exit fiber optic path and to direct the photon to the T2P module. 4. The photonic quantum memory of claim 1 , wherein the first controllable mirror comprises: a two-by-two optical coupler; and a fiber optic loop, wherein the two-by-two optical coupler includes a first port coupled to the entrance fiber optic path, a second port coupled to a first end of the fiber optic loop, a third port coupled to a second end of the fiber optic loop, and a fourth port coupled to the storage fiber optic path. 5. The photonic quantum memory of claim 4 , wherein the two-by-two optical coupler is configured to: receive a photon of the time-bin entangled photon pair with the second polarization orientation on the first port from the entrance fiber optic path; direct via the second port a first component of the photon onto the first end of the fiber optic loop; direct via the third port a second component of the photon onto the second end of the fiber optic loop; receive on the third port the first component of the photon; receive on the second port the second component of the photon; and direct the first and second components solely to the fourth port onto the storage fiber optic path via constructive interference. 6. The photonic quantum memory of claim 5 , wherein the fiber optic loop comprises a phase shifter, coupled between the second end of the fiber optic loop and a halfway point of the fiber optic loop, the phase shifter configured to adjust a relative phase shift between the first and second components of the photon. 7. The photonic quantum memory of claim 1 , wherein the second controllable mirror comprises: a two-by-two optical coupler; and a fiber optic loop, wherein the two-by-two optical coupler includes a first port coupled to the exit fiber optic path, a second port coupled to a first end of the fiber optic loop, a third port coupled to a second end of the fiber optic loop, and a fourth port coupled to the storage fiber optic path. 8. The photonic quantum memory of claim 7 , wherein the two-by-two optical coupler is configured to: receive a photon of the time-bin entangled photon pair with the second polarization orientation on the fourth port from the storage fiber optic path; direct via the second port a first component of the photon onto the first end of the fiber optic loop; direct via the third port a second component of the photon onto the second end of the fiber optic loop; receive on the third port the first component of the photon; and receive on the second port the second component of the photon. 9. The photonic quantum memory of claim 8 , wherein the two-by-two optical coupler is further configured to: direct the first and second components of the photon via the fourth port onto the storage fiber optic path or via the first port onto the exit fiber optic path, responsive to a relative phase shift between the first and second components of the photon. 10. The photonic quantum memory of claim 1 , wherein the storage comprises: a two-by-two optical switch having a first port, a second port, a third port, and a fourth port; a first delay line having a first end coupled to the third port of the two-by-two optical switch and a second end capped by a first mirror; and a second delay line having a first end coupled to the fourth port of the two-by-two optical switch and a second end capped by a second mirror. 11. The photonic quantum memory of claim 10 , wherein the two-by-two optical switch is configured to: receive a photon of the time-bin entangled photon pair via the first port; direct the photon via the fourth port onto the second delay line; direct the photon via the third port onto the first delay line; and receive the photon from the first delay line on the third port. 12. The photonic quantum memory of claim 11 , wherein the two-by-two optical switch is further configured, responsive to a relative phase shift, to: direct the the photon via the second port out of the storage; or direct the photon via the fourth port onto the second delay line. 13. The photonic quantum memory of claim 10 , wherein the two-by-two optical switch comprises a Mach Zehnder Interferometer. 14. The photonic quantum memory of claim 1 , wherein the storage comprises: a first controllable mirror having a first port and a second port; a second controllable mirror having a first port and a second port; and a delay line having a first end coupled to the second port of the first controllable mirror and a second end coupled to first port of the second controllable mirror. 15. The photonic quantum memory of claim 14 , wherein the first controllable mirror is configured to receive a photon of the time-bin entangled photon pair on the first port and to couple the photon via the second port to the delay line. 16. The photonic quantum memory of claim 15 , wherein the second controllable mirror is configured to receive the photon on the first port from the delay line, and to reflect the photon via the first port onto the delay line or direct the photon via the second port out of the storage. 17. The photonic quantum memory of claim 14 , wherein at least one of the first and second controllable mirrors comprises an electro-optical loop mirror. 18. A photonic quantum memory, comprising: a first basis conversion module configured to receive a polarization-based photon and to produce a time-bin photon with a first polarization orientation; a storage configured to: store the time-bin photon with the first polarization orientation, and convert the time-bin photon with the first polarization orientation to a time-bin photon with a second polarization orientation; wherein the storage comprises a linear race track photonic memory with: an entrance fiber optic path; an exit fiber optic path; a first controllable mirror coupled to the entrance fiber optic path; a second controllable mirror coupled to the exit fiber optic path; and a storage fiber