Laser & Optoelectronics Progress, Volume. 53, Issue 4, 41402(2016)
Bad-Cavity Raman Laser Based on Lattice-Trapped Cesium Atoms
[1] [1] Chou C W, Hume D B, Koelemeij J C J, et al.. Frequency comparison of two high-accuracy Al+ optical clocks[J]. Phys RevLett, 2010, 104: 070802.
[2] [2] Tamm C, Weyers S, Lipphardt B, et al.. Stray-field-induced quadrupole shift and absolute frequency of the 688 THz 171Yb+single-ion optical frequency standard[J]. Phys Rev A, 2009, 80: 043403.
[3] [3] Birnbaum K M, Boca A, Miller R, et al.. Photon blockade in an optical cavity with one trapped atom[J]. Nature, 2005, 436: 87-90.
[4] [4] Marshall W, Simon C, Penrose R, et al.. Towards quantum superpositions of a mirror[J]. Phys Rev Lett, 2003, 91: 130401.
[5] [5] Müller H, Herrmann S, Braxmaier C, et al.. Modern Michelson-Morley experiment using cryogenic optical resonators[J].Phys Rev Lett, 2003, 91: 020401.
[6] [6] Jiang Y Y, Ludlow A D, Lemke N D, et al.. Making optical atomic clocks more stable with 10-16 level laser stabilization[J].Nature Photon, 2011, 5: 158-161.
[7] [7] Young B C, Cruz F C, Itano W M, et al.. Visible lasers with subhertz linewidths[J]. Phys Rev Lett, 1999, 82: 3799-3802.
[8] [8] Meiser D, Ye J, Carlson D R, et al.. Prospects for a millihertz-linewidth laser[J]. Phys Rev Lett, 2009, 102: 163601.
[9] [9] Chen J B. Active optical clock[J]. Chin Sci Bull, 2009, 54(3): 348-352.
[10] [10] Wang Y Q. Optical clocks based on stimulated emission radiation[J]. Chin Sci Bull, 2009, 54(3): 347.
[11] [11] Yu D S, Chen J B. Laser theory with finite atom-field time[J]. Phys Rev A, 2008, 78: 013846.
[12] [12] Bassani F, Forney J J, Quattropani A. Choice of gauge in two-photon transitions: 1s-2s transition in atomic hydrogen[J].Phys Rev Lett, 1977, 39(17): 1070-1073.
[13] [13] Hemmerich A, H nsch T W. Two-dimensional atomic crystal bound by light[J]. Phys Rev Lett, 1993, 70: 410-413.
[14] [14] Dicke R H. Coherence in spontaneous radiation processes[J]. Phys Rev, 1954, 93(1): 99-110.
[15] [15] Haake F, Kolobov M I, Fabre C, et al.. Superradiant laser[J]. Phys Rev Lett, 1993, 71(7): 995-998.
[16] [16] Bohnet J G, Chen Z L, Weiner J M, et al.. A steady-state superradiant laser with less than one intracavity photon[J]. Nature,2012, 484: 78-81.
[17] [17] Wang Y F, Chen J B. Superradiant laser with ultra-narrow linewidth based on 40Ca[J]. Chin Phys Lett, 2012, 29(7): 073202.
[18] [18] Meiser D, Holland M J. Steady-state superradiance with alkaline-earth-metal atoms[J]. Phys Rev A, 2010, 81: 033847.
[19] [19] Chen J B, Chen X Z. Optical lattice laser[C]. Proceedings of 2005 IEEE International Frequency Control Symposium, 2005:608-610.
[20] [20] Zang X, Zhang T, Chen J. Magic wavelengths for a lattice trapped rubidium four-level active optical clock[J]. Chin Phys Lett,2012, 29: 090601.
[21] [21] Zhang T, Wang Y, Zang X, et al.. Active optical clock based on four-level quantum system[J]. Chin Sci Bull, 2013, 58: 2033-2038.
[22] [22] Zhang S N, Wang Y F, Wang D Y, et al.. A scheme of potassium atom four level active optical clock[J]. Chin Phys Lett, 2013,30: 040601.
[23] [23] Kazakov G A, Schumm T. Active optical frequency standard using sequential coupling of atomic ensembles[J]. Phys RevA, 2013, 87: 013821.
[24] [24] Chalupczak W, Szymaniec K, Henderson D. Cooling in an optical lattice for a caesium fountain frequency standard[J]. IEEETrans Instrum Meas, 2005, 54(2): 837-841.
[25] [25] Dion C M, Sjolund P, Petra S J H, et al.. Time dependence of laser cooling in optical lattices[J]. Europhys Lett, 2005, 72(3):369-375.
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Peng Yu, Liu Pengfei, Li Wei. Bad-Cavity Raman Laser Based on Lattice-Trapped Cesium Atoms[J]. Laser & Optoelectronics Progress, 2016, 53(4): 41402
Category: Lasers and Laser Optics
Received: Oct. 20, 2015
Accepted: --
Published Online: Apr. 5, 2016
The Author Email: Yu Peng (pengyu@mail.tsinghua.edu.cn)