Robust polarization-entangled quantum source from atomic ensemble and implementation methods

1 . A robust polarization-entangled quantum source from an atomic ensemble comprising: an atomic vapor cell containing rubidium ( 87 Rb) atoms; and a processor configured to generate a photon pair of a signal and an idler from the atomic vapor cell by traveling a coupling laser and a pump laser in opposite directions with respect to the atomic vapor cell. 2 . The robust polarization-entangled quantum source of claim 1 , wherein the coupling laser is a horizontally polarized 776 nanometer (nm) laser, the pump laser is a vertically polarized 780 nm laser, and the coupling laser and the pump laser simultaneously travel in opposite directions toward the atomic vapor cell at positions spaced apart from the atomic vapor cell at the same distance. 3 . The robust polarization-entangled quantum source of claim 2 , wherein the processor generates the photon pair in which the signal and the idler have a perpendicular polarization relationship of horizontal polarization/vertical polarization or vertical polarization/horizontal polarization by the horizontally polarized coupling laser and the vertically polarized pump laser. 4 . The robust polarization-entangled quantum source of claim 2 , wherein the coupling laser and the pump laser lock a laser frequency at +1 gigahertz (GHz) outside a Doppler broadening region to reduce unrelated photon pairs generated by photon resonance. 5 . The robust polarization-entangled quantum source of claim 1 , wherein the atomic vapor cell is a glass-type cell configured to keep a gas of the rubidium ( 87 Rb) atoms warm. 6 . The robust polarization-entangled quantum source of claim 1 , further comprising: a prism mirror configured to separate a path of the generated photon pair from the coupling laser and the pump laser; a single photon detector (SPD) configured to detect a photon pair satisfying a phase matching condition among the photon pairs input along the separated path; a ½λ-phase delay plate (half-wave plate: HWP) and a ¼λ-phase delay plate (quarter-wave plate: QWP) configured to control a Bell state for the detected photon pair; and a polarizer (P) configured to observe the Bell state according to polarization for the photon pair for which the Bell state is controlled. 7 . An implementation method of a robust polarization-entangled quantum source from an atomic ensemble, the method comprising: preparing an atomic vapor cell containing rubidium ( 87 Rb) atoms; and generating a photon pair of a signal and an idler from the atomic vapor cell by traveling a coupling laser and a pump laser in opposite directions with respect to the atomic vapor cell. 8 . The method of claim 7 , wherein the coupling laser is a horizontally polarized 776 nm laser, the pump laser is a vertically polarized 780 nm laser, and the coupling laser and the pump laser simultaneously travel in opposite directions toward the atomic vapor cell at positions spaced apart from the atomic vapor cell at the same distance. 9 . The method of claim 8 , wherein the generating of the photon pair comprises generating the photon pair in which the signal and the idler have a perpendicular polarization relationship of horizontal polarization/vertical polarization or vertical polarization/horizontal polarization by the horizontally polarized coupling laser and the vertically polarized pump laser. 10 . The method of claim 8 , wherein the coupling laser and the pump laser lock a laser frequency at +1 GHz outside a Doppler broadening region to reduce unrelated photon pairs generated by photon resonance. 11 . The method of claim 7 , wherein the preparing of the atomic vapor cell comprises preparing a glass-type cell configured to keep a gas of the rubidium ( 87 Rb) atoms warm. 12 . The method of claim 7 , further comprising: at a prism mirror, separating a path of the generated photon pair from the coupling laser and the pump laser; at a single photon detector (SPD), detecting a photon pair satisfying a phase matching condition among the photon pairs input along the separated path; at a ½λ-phase delay plate (half-wave plate: HWP) and a ¼λ-phase delay plate (quarter-wave plate: QWP), controlling a Bell state for the detected photon pair; and at a polarizer (P), observing the Bell state according to polarization for the photon pair for which the Bell state is controlled. 13 . A non-transitory computer-readable recording medium on which a program for executing the method of claim 7 is recorded.