Microscopic electronic structure tomography of Rydberg macrodimers

Simon Hollerith, Jun Rui, Antonio Rubio-Abadal, K. Srakaew, David Wei, J. Zeiher, C. Gross, I. Bloch
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引用次数: 5

Abstract

Precise control and study of molecules is challenging due to the variety of internal degrees of freedom and local coordinates that are typically not controlled in an experiment. Employing quantum gas microscopy to position and resolve the atoms in Rydberg macrodimer states solves almost all of these challenges and enables unique access to the molecular frame. Here, we demonstrate the power of this approach and present first photoassociation studies for different molecular symmetries in which the molecular orientation relative to an applied magnetic field, the polarization of the excitation light and the initial atomic state are fully controlled. The observed characteristic dependencies allow for an electronic structure tomography of the molecular state. We additionally observe an orientation-dependent Zeeman shift and reveal a significant influence on it caused by the hyperfine interaction of the macrodimer state. Finally, we demonstrate controlled engineering of the electrostatic binding potential by opening a gap in the energetic vicinity of two crossing pair potentials.
Rydberg大二聚体的显微电子结构层析成像
分子的精确控制和研究具有挑战性,因为内部自由度和局部坐标的变化通常在实验中无法控制。利用量子气体显微镜来定位和解析里德堡大二聚体状态的原子,几乎解决了所有这些挑战,并使我们能够独特地进入分子框架。在这里,我们证明了这种方法的力量,并首次提出了不同分子对称性的光关联研究,其中分子取向相对于外加磁场,激发光的偏振和初始原子状态是完全控制的。观察到的特征依赖关系允许对分子状态进行电子结构断层扫描。我们还观察到取向依赖的塞曼位移,并揭示了由宏观二聚体状态的超精细相互作用引起的对其的显著影响。最后,我们演示了通过在两个交叉对电位附近打开一个能隙来控制静电结合电位的工程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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