Background noise analysis of laser interferometer for
test of TDI technology on ground

doi:10.3969/j.issn.1007-5461.2024.04.009

Abstract

Abstract: For space gravitational wave detection, as the lengths of laser interferometer arms are not matched, the laser frequency noise cannot be eliminated in common mode, leading to the weak interfering signals being submerged in large residual laser frequency noise. By time-shifting and linearly combining independent interfering signals, laser frequency noise can be greatly eliminated as laser interferometry with virtual equal interferometer arm lengths. Such a technique is called time delay interferometry (TDI). In order to experimentally validate that TDI technique can reduce the influence of laser frequency noise on gravitational wave detection to 3 × 10-7 Hz/ Hz at Fourier frequency of 1 mHz on the ground, it is necessary to analyze the main frequency noise sources of laser interferometer. Based on experimental measurement and calculation analysis, experimental parameters of the laser interferometer are derived to meet the noise requirement of gravitational wave detection, including the maximum length difference between interferometer arms, laser frequency stability, air pressure stability, laser power stability and temperature stability of experimental setups.

Key words: laser techniques, gravitational wave detection in space, noise analysis of laser interferometer; time-delay interferometry, laser frequency noise

CLC Number:

ZUO Lingyun, SHI Haosen, YAO Yuan, JIANG Yanyi, MA Longsheng. Background noise analysis of laser interferometer for test of TDI technology on ground[J]. Chinese Journal of Quantum Electronics, 2024, 41(4): 649-658.

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Background noise analysis of laser interferometer for test of TDI technology on ground

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