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    Journals >Laser & Optoelectronics Progress >Volume 60 >Issue 17 >Page 1736001 > Article
    • Laser & Optoelectronics Progress
    • Vol. 60, Issue 17, 1736001 (2023)
    [in Chinese]
    Yuqing Li1,2, Huiying Du1, Yunfei Wang1, Jizhou Wu1,2..., Wenliang Liu1,2, Peng Li3, Yongming Fu3, Jie Ma1,2,*, Liantuan Xiao1,2 and Suotang Jia1,2|Show fewer author(s)
    Author Affiliations
  • 1State Key Laboratory of Quantum Optics and Quantum Optics Devices, Institute of Laser Spectroscopy, College of Physics and Electronics Engineering, Shanxi University, Taiyuan 030006, Shanxi , China
  • 2Collaborative Innovation Center of Extreme Optics, Shanxi University, Taiyuan 030006, Shanxi , China
  • 3College of Physics and Electronic Engineering, Shanxi University, Taiyuan 030006, Shanxi , China
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    DOI: 10.3788/LOP231417 Cite this Article Set citation alerts
    Yuqing Li, Huiying Du, Yunfei Wang, Jizhou Wu, Wenliang Liu, Peng Li, Yongming Fu, Jie Ma, Liantuan Xiao, Suotang Jia. [J]. Laser & Optoelectronics Progress, 2023, 60(17): 1736001 Copy Citation Text show less
    References

    [1] Luo X Y, Zou Y Q, Wu L N et al. Deterministic entanglement generation from driving through quantum phase transitions[J]. Science, 355, 620-623(2017).

    [2] Bloch I. Quantum coherence and entanglement with ultracold atoms in optical lattices[J]. Nature, 453, 1016-1022(2008).

    [3] Dai H N, Yang B, Reingruber A et al. Generation and detection of atomic spin entanglement in optical lattices[J]. Nature Physics, 12, 783-787(2016).

    [4] Hu J Z, Feng L, Zhang Z D et al. Quantum simulation of Unruh radiation[J]. Nature Physics, 15, 785-789(2019).

    [5] Li Y Q, Zhang J H, Wang Y F et al. Atom-optically synthetic gauge fields for a noninteracting Bose gas[J]. Light: Science & Applications, 11, 13(2022).

    [6] Wang Y F, Zhang J H, Li Y Q et al. Observation of interaction-induced mobility edge in an atomic Aubry-André wire[J]. Physical Review Letters, 129, 103401(2022).

    [7] Ludlow A D, Boyd M M, Ye J et al. Optical atomic clocks[J]. Reviews of Modern Physics, 87, 637(2015).

    [8] Lücke B, Scherer M, Kruse J et al. Twin matter waves for interferometry beyond the classical limit[J]. Science, 334, 773-776(2011).

    [9] Kong D H, Wang Z H, Guo F et al. A transportable optical lattice clock at the National Time Service Center[J]. Chinese Physics B, 29, 070602(2020).

    [10] Wang Y F, Du H Y, Li Y Q et al. Testing universality of Feynman-Tan relation in interacting Bose gases using high-order Bragg spectra[J]. Light: Science & Applications, 12, 50(2023).

    [11] Zhang J Y, Chen L L, Cheng Y A et al. Movable precision gravimeters based on cold atom interferometry[J]. Chinese Physics B, 29, 093702(2020).

    [12] Marti G E, Olf R, Vogt E et al. Two-element Zeeman slower for rubidium and lithium[J]. Physical Review A, 81, 043424(2010).

    [13] Hopkins S A, Butler K, Guttridge A et al. A versatile dual-species Zeeman slower for caesium and ytterbium[J]. Review of Scientific Instruments, 87, 043109(2016).

    [14] Phillips W D, Metcalf H. Laser deceleration of an atomic beam[J]. Physical Review Letters, 48, 596-599(1982).

    [15] Dieckmann K, Spreeuw R J C, Weidemüller M et al. Two-dimensional magneto-optical trap as a source of slow atoms[J]. Physical Review A, 58, 3891-3895(1998).

    [16] Tiecke T G, Gensemer S D, Ludewig A et al. High-flux two-dimensional magneto-optical-trap source for cold lithium atoms[J]. Physical Review A, 80, 013409(2009).

    [17] Götz S, Höltkemeier B, Hofmann C S et al. Versatile cold atom target apparatus[J]. Review of Scientific Instruments, 83, 073112(2012).

    [18] Streed E W, Chikkatur A P, Gustavson T L et al. Large atom number Bose-Einstein condensate machines[J]. Review of Scientific Instruments, 77, 023106(2006).

    [19] Modugno G, Ferrari G, Roati G et al. Bose-Einstein condensation of potassium atoms by sympathetic cooling[J]. Science, 294, 1320-1322(2001).

    [20] Weber T, Herbig J, Mark M et al. Bose-Einstein condensation of cesium[J]. Science, 294, 232-235(2003).

    [21] Bowden W, Gunton W, Semczuk M et al. An adaptable dual species effusive source and Zeeman slower design demonstrated with Rb and Li[J]. Review of Scientific Instruments, 87, 043111(2016).

    [22] Paris-Mandoki A, Jones M D, Nute J et al. Versatile cold atom source for multi-species experiments[J]. Review of Scientific Instruments, 85, 113103(2014).

    [23] Foot C J[M]. Atomic physics, 181(2005).

    [24] Dedman C J, Nes J, Hanna T M et al. Optimum design and construction of a Zeeman slower for use with a magneto-optic trap[J]. Review of Scientific Instruments, 75, 5136-5142(2004).

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    Yuqing Li, Huiying Du, Yunfei Wang, Jizhou Wu, Wenliang Liu, Peng Li, Yongming Fu, Jie Ma, Liantuan Xiao, Suotang Jia. [J]. Laser & Optoelectronics Progress, 2023, 60(17): 1736001
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