Frequency-Shift of a Frequency Stabilized Laser Based on Zeeman Effect
WEI Rong, DENG Jian-Liao, QIAN Yong, ZHANG Yu, WANG Yu-Zhu
Key Laboratory for Quantum Optics, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800
Frequency-Shift of a Frequency Stabilized Laser Based on Zeeman Effect
WEI Rong;DENG Jian-Liao;QIAN Yong;ZHANG Yu;WANG Yu-Zhu
Key Laboratory for Quantum Optics, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800
关键词 :
32.60.+i ,
06.30.Ft ,
42.50.Vk
Abstract : We introduce a new method of frequency-shifting for a diode laser in laser cooling experiments, the method is based on the Zeeman effect of 87 Rb atoms. The laser frequency is stabilized by absorption spectrum line of atoms in magnetic field. We show that a magnetic field can be added up to 10-2 T. The corresponding frequency shift is 102 MHz and the response time is about 1 ms. The large range of the frequency shift is sufficient for laser-cooling experiments.
Key words :
32.60.+i
06.30.Ft
42.50.Vk
出版日期: 2003-10-01
引用本文:
WEI Rong;DENG Jian-Liao;QIAN Yong;ZHANG Yu;WANG Yu-Zhu. Frequency-Shift of a Frequency Stabilized Laser Based on Zeeman Effect[J]. 中国物理快报, 2003, 20(10): 1714-1717.
链接本文:
https://cpl.iphy.ac.cn/CN/
或
https://cpl.iphy.ac.cn/CN/Y2003/V20/I10/1714
[1]
WANG Ping;;LI Run-Bing;;YAN Hui;;WANG Jin;ZHAN Ming-Sheng;. Demonstration of a Sagnac-Type Cold Atom Interferometer with Stimulated Raman Transitions
[2]
ZHAN Zhi-Ming;YANG Wen-Xing;LI Wei-Bin;LI Jia-Hua. Efficient Scheme for Greenberger--Horne--Zeilinger State and Cluster State with Trapped Ions
[3]
LIU Yang;YUN Min;YIN Jian-Ping. Controllable Magnetic Focusing of Cold Atoms on a Chip
[4]
BAI Li-Hua;ZHANG Jing-Tao;WANG Yi;XU Zhi-Zhan. Pondermotive Shift of Photoelectron Spectra in Intense Laser Field
[5]
XIE Chun-Xia;WANG Zhengling;YIN Jian-Ping. A Novel Gravito-Optical Surface Trap for Neutral Atoms
[6]
WU Qin-Qin;ZHOU Lan;KUANG Le-Man. Linear Optical Implementation of Quantum Clock Synchronization Algorithm
[7]
ZHANG Xiao-Mingv;ZHANG Jing-Tao;BAI Li-Hua⊃GONG Qi-Huang;XU Zhi-Zhan;. Duration-Dependent Asymmetry in Photoionization of H atoms in Few-Cycle Laser Pulses
[8]
YU Yong-Li;ZHAO Xia;LI Hong-Yun;GUO Wen-Hao;LIN Sheng-Lu. Autocorrelation Function of Hydrogen Atoms in Magnetic Fields
[9]
WU Li-Jin;SHI Ting-Yun;GAO Ke-Lin. Effect of Laser Cooling on Frequency Standard of Single Ca+ Ion Trapped in a Radio-Frequency Paul Trap
[10]
YANG Guang-Can;LIU Yong;CHI Xian-Xing. Photodetachment of H- in a Static Electric Field near a Surface
[11]
BIAN Feng-Gang;WEI Rong;JIANG Hai-Feng;WANG Yu-Zhu. A Movable-Cavity Cold Atom Space Clock
[12]
WANG Zheng-Ling;YIN Jian-Ping. Average Dissipative and Dipole Forces on a Three-Level Atom in a Laguerre--Gaussian Beam
[13]
AI Meng;YIN Jian-Ping. A Novel Atomic Guiding Using a Blue-Detuned TE01 Mode in Hollow Metallic Waveguides
[14]
ZENG Hao-Sheng;HU Ai-Qin;LIU Qiong;KUANG Le-Man. Direct Measurement of Squeezing in the Motion of Trapped Ions
[15]
ZHANG Hai-Chao;ZHANG Peng-Fei;XU Xin-Ping; HAN Jiu-Rong;WANG Yu-Zhu. Trapping of Neutral Atoms with a Radio-Frequency Field
2003, Vol. 20 
