Enhanced sensitivity to ultralight bosonic dark matter in the spectra of the linear radical SrOH

arXiv: Atomic Physics Pub Date : 2018-05-21 DOI:10.1103/PHYSREVA.103.043313

I. Kozyryev, Z. Lasner, J. Doyle

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引用次数: 24

Abstract

Coupling between Standard Model particles and theoretically well-motivated ultralight dark matter (UDM) candidates can lead to time variation of fundamental constants including the proton-to-electron mass ratio $\mu\equiv m_{p}/m_{e}\approx1836$. The presence of nearly-degenerate vibrational energy levels of different character in polyatomic molecules can result in significantly enhanced relative energy shifts in molecular spectra originating from $\partial_{t}\mu$, relaxing experimental complexity required for high-sensitivity measurements. We analyze the amplification of UDM effects in the spectrum of laser-cooled strontium monohydroxide (SrOH). SrOH is the first and, so far, the only polyatomic molecule to be directly laser cooled to sub-millikelvin temperatures, opening the possibility of long experimental coherence times. Because of the high enhancement factors ($\left|Q_{\mu}\right|\approx10^{3}$), measurements of the $\tilde{X}\left(200\right)\leftrightarrow\tilde{X}\left(03^{1}0\right)$ rovibrational transitions of SrOH in the microwave regime can result in $\sim10^{-17}$ fractional uncertainty in $\delta\mu/\mu$ with one day of integration. Furthermore, ultracold SrOH provides a promising platform for suppressing systematic errors. More complex SrOR radicals with additional vibrational modes arising from larger ligands R could lead to even greater enhancement factors.

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线性自由基SrOH光谱对超轻玻色子暗物质的灵敏度增强

标准模型粒子与理论上动机良好的超轻暗物质(UDM)候选者之间的耦合会导致质子与电子质量比等基本常数的时间变化 $\mu\equiv m_{p}/m_{e}\approx1836$．多原子分子中不同性质的近简并振动能级的存在会导致分子光谱中相对能量位移的显著增强 $\partial_{t}\mu$，降低了高灵敏度测量所需的实验复杂性。本文分析了激光冷却氢氧化锶(SrOH)光谱中UDM效应的放大。slo是迄今为止第一个也是唯一一个直接被激光冷却到亚毫开尔文温度的多原子分子，开启了长实验相干时间的可能性。由于高增强因子($\left|Q_{\mu}\right|\approx10^{3}$)，测量 $\tilde{X}\left(200\right)\leftrightarrow\tilde{X}\left(03^{1}0\right)$ slo在微波状态下的振动跃迁会导致 $\sim10^{-17}$ 的分数不确定度 $\delta\mu/\mu$ 一天的整合。此外，超冷slo为抑制系统误差提供了一个有前途的平台。更复杂的SrOR自由基与更大的配体R产生的附加振动模式可能导致更大的增强因子。

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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arXiv: Atomic Physics

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