mSTAR:使用高性能光学频率参考来测试空间中的狭义相对论

时间频率公报 Pub Date : 2015-04-12 DOI:10.1109/FCS.2015.7138789

T. Schuldt, S. Saraf, A. Stochino, K. Doringshoff, S. Buchman, G. Cutler, J. Lipa, Si Tan, J. Hanson, B. Jaroux, C. Braxmaier, N. Gurlebeck, S. Herrmann, C. Lammerzahl, A. Peters, A. Alfauwaz, Abdulaziz Alhussien, Badr N. Alsuwaidan, T. Al Saud, H. Dittus, U. Johann, S. P. Worden, R. Byer

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引用次数: 5

摘要

迷你时空不对称研究(mSTAR)任务旨在通过在近地轨道上进行时钟对比实验来验证狭义相对论。使用在轨道时间不稳定在或低于1·10-15水平的时钟，肯尼迪-桑代克系数的测量精度将比目前地面实验设定的极限高两个数量级。在目前的基线设计中，mSTAR采用了基于分子碘的光学绝对频率参考和基于高精细光学腔的长度参考。目前的工作目标是两个时钟的空间兼容设计和提高腔参考的长期稳定性。在正在进行的A阶段研究中，研究了在沙特4号公共汽车上容纳实验的可行性。

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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mSTAR: Testing special relativity in space using high performance optical frequency references

The proposed space mission mini Space-Time Asymmetry Research (mSTAR) aims at a test of special relativity by performing a clock-clock comparison experiment in a low-Earth orbit. Using clocks with instabilies at or below the 1·10-15 level at orbit time, the Kennedy-Thorndike coefficient will be measured with an up to two orders of magnitude higher accuracy than the current limit set by ground-based experiments. In the current baseline design, mSTAR utilizes an optical absolute frequency reference based on molecular iodine and a length-reference based on a high-finesse optical cavity. Current efforts aim at a space compatible design of the two clocks and improving the long-term stability of the cavity reference. In an ongoing Phase A study, the feasibility of accommodating the experiment on a SaudiSat 4 bus is investigated.

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时间频率公报

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