Share with Facebook
Tweet This
Post on reddit
Share with LinkedIn
Add to CiteULike
Add to Mendeley
Add to BibSonomy
Abstract
Long qubit coherence and efficient atom–photon coupling are essential for advanced applications in quantum communication. One technique to maintain coherence is dynamical decoupling (DD), where a periodic sequence of refocusing pulses is employed to reduce the interaction of the system with the environment. We experimentally study the implementation of DD on an optically trapped, spin-polarized $^{87}{\rm Rb}$ atom. We use the two magnetic-sensitive $5{S_{1/2}}$ Zeeman levels $|F = 2,{m_F} = - 2\rangle$ and $|F = 1,{m_F} = - 1\rangle$ as qubit states, motivated by the possibility of coupling $|F = 2,{m_F} = - 2\rangle$ to $5{P_{3/2}}$ the excited state $|F^\prime = 3,{m^\prime _F} = - 3\rangle$ via a closed optical transition. With more refocusing pulses in the DD technique, we manage to extend the coherence time from 38(3) µs to around 7 ms. We also observe a strong correlation between the motional states of the atom and the qubit coherence after the refocusing, which can be used as a measurement basis to resolve trapping parameters.
© 2021 Optical Society of America
Full Article | PDF ArticleMore Like This
Yuelong Wu, Lirong Chen, Zhongxiao Xu, and Hai Wang
Opt. Express 22(19) 23360-23371 (2014)
Shi Yu, Peng Xu, Xiaodong He, Min Liu, Jin Wang, and Mingsheng Zhan
Opt. Express 21(26) 32130-32140 (2013)
Zhenlian Shi, Ziliang Li, Pengjun Wang, Khan Sadiq Nawaz, Liangchao Chen, Zengming Meng, Lianghui Huang, and Jing Zhang
J. Opt. Soc. Am. B 38(4) 1229-1234 (2021)