Robust laboratory limits on a cosmological spatial gradient in the electromagnetic fine-structure constant from accelerometer experiments

Y. Stadnik
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Abstract

Quasar absorption spectral data indicate the presence of a spatial gradient in the electromagnetic fine-structure constant $\alpha$ on cosmological length scales. We point out that experiments with accelerometers, including torsion pendula and atom interferometers, can be used as sensitive probes of cosmological spatial gradients in the fundamental constants of nature, which give rise to equivalence-principle-violating forces on test masses. Using laboratory data from the Eot-Wash experiment, we constrain spatial gradients in $\alpha$ along any direction to be $|\mathbf{\nabla} \alpha / \alpha| < 6.6 \times 10^{-4}~(\textrm{Glyr})^{-1}$ at $95\%$ confidence level. Our result represents an order of magnitude improvement over laboratory bounds from clock-based searches for a spatial gradient in $\alpha$ directed along the observed cosmological $\alpha$-dipole axis.
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加速度计实验中电磁精细结构常数的宇宙空间梯度的鲁棒实验室限制
类星体吸收光谱数据表明,在宇宙长度尺度上,电磁精细结构常数$\alpha$存在空间梯度。我们指出,用加速度计进行的实验,包括扭摆和原子干涉仪,可以作为宇宙空间梯度的敏感探测器,在自然界的基本常数中,这些基本常数会产生对测试质量的等效原理违反力。使用Eot-Wash实验的实验室数据,我们将$\alpha$沿任何方向的空间梯度约束为$|\mathbf{\nabla} \alpha / \alpha| < 6.6 \times 10^{-4}~(\textrm{Glyr})^{-1}$,置信水平为$95\%$。我们的结果代表了一个数量级的改进实验室边界从时钟为基础的搜索空间梯度在$\alpha$沿着观测到的宇宙$\alpha$偶极子轴。
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