腔量子电动力学(Cavity-QED)旨在研究受限特定空间,如微光学腔中的原子与光场作用的量子行为。在原子与腔场作用达到一定程度以后,光子和原子相互影响变得很强烈,从而导致一系列新的效应,比如原子自发辐射反转、非经典光场产生等。利用原子冷却手段,腔QED已经在基本物理的研究中引起了人们的广泛关注,它将在各种微型光量子器件、量子信息科学等获得应用。本实验室目前主要利用远离共振的光场对中性原子产生的偶极力进行单原子控制的实验研究,在此基础上利用低损耗微腔实现光场与原子的作用,并研究特定条件下原子的辐射特性以及光场与原子强耦合相互作用。
Probing spontaneous wave-function collapse with entangled levitating nanospheres
Jing Zhang, Tiancai Zhang, Jie Li
Wave-function collapse models are considered to be the modified theories of standard quantum mechanics
at the macroscopic level. By introducing nonlinear stochastic terms in the Schr¨odinger equation, these models
(different from standard quantum mechanics) predict that it is fundamentally impossible to prepare macroscopic
systems in macroscopic superpositions. The validity of these models can only be examined by experiments, and
hence efficient protocols for these kinds of experiments are greatly needed. Here we provide a protocol that
is able to probe the postulated collapse effect by means of the entanglement of the center-of-mass motion of
two nanospheres optically trapped in a Fabry-P´erot cavity. We show that the collapse noise results in a large
reduction of the steady-state entanglement, and the entanglement, with and without the collapse effect, shows
distinguishable scalings with certain system parameters, which can be used to determine unambiguously the
effect of these models.
PHYSICAL REVIEW A 95, 012141 (2017)
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Experimental test of Bohr’s complementarity principle with single neutral atoms
Zhihui Wang, Yali Tian, Chen Yang, Pengfei Zhang, Gang Li,Tiancai Zhang
An experimental test of the quantum complementarity principle based on single neutral atoms trapped in
a blue detuned bottle trap was here performed. A Ramsey interferometer was used to assess the wavelike
behavior or particlelike behavior with second π/2 rotation on or off. The wavelike behavior or particlelike
behavior is characterized by the visibility V of the interference or the predictability P of which-path information,
respectively. The measured results fulfill the complementarity relation P2 + V2≤ 1. Imbalance losses were
deliberately introduced to the system and we find the complementarity relation is then formally “violated.” All
the experimental results can be completely explained theoretically by quantum mechanicswithout considering the
interference betweenwave and particle behaviors. This observation complements existing information concerning
Bohr’s complementarity principle based on wave-particle duality of a massive quantum system.
PHYSICAL REVIEW A 94, 062124 (2016)
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High-efficiency blue light generation at
426 nm in low pump regime
Jianfeng Tian, Chen Yang1, Jia Xue1, Yuchi Zhang, Gang Li,Tiancai Zhang
We report high-efficiency Ti:sapphire-laser-based frequency doubling at the cesium D2 line
852 nm using a 20 mm-long periodically-poled potassium titanyl phosphate crystal in a bow-tie
four-mirror ring enhancement cavity. The relatively complete cavity design procedure is
presented. Focusing that is over twice as loose as optimal focusing is used, and both the
fundamental frequency wave and second harmonic beam absorption-induced thermal lensing
effects are weakened. Blue light of 210mW at 426 nm, where absorption is severe, was obtained
with 310mW mode-matched fundamental light, corresponding to conversion efficiency of up to
67%. The blue light beam power showed 1.5% RMS fluctuation over 40 min.
J. Opt. 18,055506 (2016)
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Experimental investigation of the statistical
distribution of single atoms in cavity
quantum electrodynamics
Jin-Jin Du, Wen-Fang Li, Rui-Juan Wen, Gang Li and Tian-Cai Zhang
The Hanbury Brown–Twiss experiment for a beam of photons or atoms can be performed
using counting experiments. We present the statistical distribution of single 133Cs atoms
detected by a high finesse microcavity, which acts as a point-like single-atom counter. The
distribution of the arrival times of the atoms and the correlation between the atoms was
obtained based on the full counting statistics of the beam emitted from the cavity. The
bunching behavior of the thermal atomic beams is clearly observable using this type of
atom–cavity system. The correlation between the cesium atoms depends on the temperature of
the atom cloud, and the corresponding parameters may be found by fitting an experimentally
measured curve using the theory of multimode thermal light.
Laser Phys. Lett., 12, 065501(2015)
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Temperature measurement of cold atoms using single-atom transits
and Monte Carlo simulation in a strongly coupled atom-cavity system
Wenfang Li, Jinjin Du, Ruijuan Wen, Pengfei Yang, Gang Li, Junjun Liang,
and Tiancai Zhang
We investigate the transmission of single-atom transits based on a strongly coupled
quantum electrodynamics system. By superposing the transit transmissions of a considerable
number of atoms, we obtain the absorption spectra of the cavity induced by single atoms and
obtain the temperature of the cold atom. The number of atoms passing through the microcavity
each release is also counted, and this number changes exponentially along with the
temperature. Monte Carlo simulations agree closely with the experimental results, and the
temperature of the cold atom is determined. Compared with the conventional time-of-flight (TOF
method, this approach avoids some uncertainties in the standard TOF and sheds new light
on determining temperature of cold atoms by counting atoms individually in a confined space.
APPLIED PHYSICS LETTERS 104, 113102 (2014)
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