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Tsai, P-J, Yuan L-P, Chen Y-C.  2023.  Fisher information analysis for quantum-enhanced parameter estimation in an electromagnetically-induced-transparency spectrum with single photons.. PHYSICAL REVIEW A. 108, 033711(2023)
Tsai, P-J, Wei Y-C, Wu B-H, Li S-X, Chen Y-C.  2020.  Theoretical study on memory-based optical converter with degenerate Zeeman states. Phys. Rev. A. 100(063843)Link
Tsai, P-J, Chen Y-C.  2018.  Ultrabright, narrow-band photon-pair source for atomic quantum memories. Quantum Sci. Technol. 3 (034005)
Tsai, P-J, Hsiao Y-F, Chen Y-C.  2020.  Quantum storage and manipulation of heralded single photons in atomic quantum memories. Phys. Rev. Research. 2(033155)Link
Tseng, Y-C, Wei Y-C, Chen Y-C.  2020.  Efficient quantum memory for heralded single photons generated by cavity-enhanced spontaneous parametric downconversion. arXiv. 2011.14948Link
Tseng, Y-C, Wei W-C, Chen Y-C.  2022.  Efficient quantum memory for photonic polarization qubits generate by cavity-enhanced spontane-ous parametric downconversion. Opt. Express. 30, 19944(2022)
Tu, MF, Ho JJ, Hsieh CC, Chen YC.  2009.  Intense SrF radical beam for molecular cooling experiments, Nov. Review of Scientific Instruments. 80:5., Number 11 AbstractWebsite

We have developed a continuous SrF radical beam for the loading of helium buffer gas cooling. The SrF molecules are efficiently generated by high-temperature chemical reaction of the solid precursor SrF(2) with boron in a graphite oven. The beam properties are characterized with laser-induced fluorescence spectroscopic method. We obtain a molecular flux of up to 2.1 x 10(15) sr(-1) s(-1) at the detection region for all rotational states. The dependence of the flux on oven temperature suggests that even higher flux is possible if a higher temperature in the oven is achieved. (C) 2009 American Institute of Physics. [doi:10.1063/1.3262631]

Tung, SK, Chen YC, Lin CW, Hsu L, Yu IA.  2000.  Cooling atoms below 100 mu K, Apr. Chinese Journal of Physics. 38:395-399., Number 2 AbstractWebsite

We capture Rb-87 atoms from room-temperature background vapor with a magneto-optical trap (MOT). The temperature of the atoms in the MOT is 320 mu K as the result of Doppler cooling. We further employ polarization gradient cooling to lower atom temperature. The factors that can affect the performance of polarization gradient cooling have been systematically studied. An atom temperature of 75 mu K has been reached with the optimized conditions. Temperatures are measured by the release and recapture method and the time of flight method. Such cold atoms are ready for the evaporative cooling which will finally realize the Bose-Einstein condensation.