用于光学晶格中原子动力学实时探测的腔探针

R. Niederriter, Chandler Schlupf, P. Hamilton
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引用次数: 6

摘要

我们提出并演示了实时亚波长腔QED测量光学晶格中原子的空间分布。最初被限制在光学腔模式的一个“陷阱”驻波中的原子被第二个“探针”驻波探测。由于频率偏移了一个自由光谱范围,陷阱的节点落在腔中心周围的${\approx}$ 10 $^4$晶格位置的探针反节点上。这种与晶格位无关的原子-腔耦合使得即使原子分布在许多晶格位上也能高灵敏度地检测原子动力学。为了证明这一点,我们在${<}$ 10 $\mu$ s内测量了20-70 $\mu$ K原子系综的温度,通过监测它们在从陷阱晶格突然释放后${\approx}$ 100 nm的膨胀。原子-腔耦合将原子动力学烙印在探针传输上。这项新技术将改进对光学晶格中的布洛赫振荡和其他原子动力学的无损检测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cavity probe for real-time detection of atom dynamics in an optical lattice
We propose and demonstrate real-time sub-wavelength cavity QED measurements of the spatial distribution of atoms in an optical lattice. Atoms initially confined in one "trap" standing wave of an optical cavity mode are probed with a second "probe" standing wave. With frequencies offset by one free spectral range, the nodes of the trap fall on the anti-nodes of the probe in the ${\approx}$10$^4$ lattice sites around the center of the cavity. This lattice site independent atom-cavity coupling enables high sensitivity detection of atom dynamics even with atoms spread over many lattice sites. To demonstrate, we measure the temperature of 20-70 $\mu$K atom ensembles in ${<}$10 $\mu$s by monitoring their expansion of ${\approx}$100 nm after sudden release from the trap lattice. Atom-cavity coupling imprints the atom dynamics on the probe transmission. The new technique will enable improved non-destructive detection of Bloch oscillations and other atom dynamics in optical lattices.
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