Simulation of residual gas noise in high-precision inertial sensors with optical readout

Fang WANG; Ming-chao SHE; Xiao-dong PENG; Li'e QIANG; Peng XU; Wen-lin TANG; Yu-zhu ZHANG

doi:10.37188/CO.2024-0186

Chinese Optics, Volume. 18, Issue 3, 612(2025)

Simulation of residual gas noise in high-precision inertial sensors with optical readout

Fang WANG^1,6, Ming-chao SHE^1,5,6, Xiao-dong PENG^1,2,3,5, Li'e QIANG^1、*, Peng XU^2,3,4,5, Wen-lin TANG¹, and Yu-zhu ZHANG¹

Author Affiliations

¹National Space Science Center, Chinese Academy of Sciences, Beijing 100190, China

²Taiji Laboratory for Gravitational Wave Universe, Hangzhou 310024, China

³Key Laboratory of Gravitational Wave Precision Measurement of Zhejiang Province, Hangzhou 310024, China

⁴Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China

⁵Hangzhou Institute for Advanced Study, UCAS, Hangzhou 310024, China

⁶University of Chinese Academy of Sciences, Beijing 100049, China

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References(24)

[1] [1] AHARONI J. The Special They of Relativity[J]. Oxfd: Clarendon Press, 1959.

[2] HOGAN C J. Gravitational wave sources from new physics[J]. AIP Conference Proceedings, 873, 30-40(2006).

[3] [3] SCHILLING G. Ripples in Spacetime: Einstein, Gravitational Waves, the Future of Astronomy[M]. Cambridge: Harvard University Press, 2017.

[4] WU Y L, HU W R, WANG J Y et al. Review and scientific objectives of spaceborne gravitational wave detection missions[J]. Chinese Journal of Space Science, 43, 589-599(2023).

[5] WANNER G. Space-based gravitational wave detection and how LISA pathfinder successfully paved the way[J]. Nature Physics, 15, 200-202(2019).

[6] [6] ARAÚJO H, BOATELLA C, CHMEISSANI M, et al. LISA LISA PathFinder, the Endeavour to detect low frequency GWs[J]. Journal of Physics: Conference Series, 2007, 66: 012003.

[7] EINSTEIN A, ROSEN N. On gravitational waves[J]. Journal of the Franklin Institute, 223, 43-54(1937).

[8] [8] WANNER G. Complex optical systems in space: numerical modelling of the heterodyne interferometry of LISA Pathfinder LISA[D]. Hannover: Gottfried Wilhelm Leibniz Universität Hannover, 2010.

[9] [9] DANZMANN K, PRINCE T A, BIRUY P, et al. LISA: unveiling a hidden universe[R]. Assessment Study Rept ESASRE, 2011, 3(2).

[10] [10] SALA L. Residual test mass acceleration in LISA Pathfinder: indepth statistical analysis physical sources[D]. Trento: University of Trento, 2023.

[11] ARMANO M, AUDLEY H, AUGER G et al. Sub-femto-g free fall for space-based gravitational wave observatories: LISA pathfinder results[J]. Physical Review Letters, 116, 231101(2016).

[12] ARMANO M, AUDLEY H, BAIRD J et al. Beyond the required LISA free-fall performance: new LISA pathfinder results down to 20 μ Hz[J]. Physical Review Letters, 120, 061101(2018).

[13] ZHANG H Y, XU P, YE Z Q et al. A systematic approach for inertial sensor calibration of gravity recovery satellites and its application to Taiji-1 mission[J]. Remote Sensing, 15, 3817(2023).

[14] [14] BADARACCO F, VAN HEIJNINGEN J V, FERREIRA E, et al. A cryogenic superconducting inertial sens f the lunar gravitational–wave antenna, the Einstein telescope selenephysics[C]. The Sixteenth Marcel Grossmann Meeting on Recent Developments in Theetical Experimental General Relativity, Astrophysics Relativistic Field Theies: Proceedings of the MG16 Meeting on General Relativity Online; 510 July 2021, Wld Scientific, 2023: 32453253.

[15] BERMÚDEZ A, HERVELLA-NIETO L, RODRÍGUEZ R. Finite element computation of the vibrations of a plate-fluid system with interface damping[J]. Computer Methods in Applied Mechanics and Engineering, 190, 3021-3038(2001).

[16] CHRISTIAN R G. The theory of oscillating-vane vacuum gauges[J]. Vacuum, 16, 175-178(1966).

[17] BAO M H, YANG H, YIN H et al. Energy transfer model for squeeze-film air damping in low vacuum[J]. Journal of Micromechanics and Microengineering, 12, 341-346(2002).

[18] SUIJLEN M A G, KONING J J, VAN GILS M A J et al. Squeeze film damping in the free molecular flow regime with full thermal accommodation[J]. Sensors and Actuators A: Physical, 156, 171-179(2009).

[19] DOLESI R, HUELLER M, NICOLODI D et al. Brownian force noise from molecular collisions and the sensitivity of advanced gravitational wave observatories[J]. Physical Review D, 84, 063007(2011).

[20] ZHAO Y J, LI G L, LIU L et al. Experimental verification of and physical interpretation for adsorption-dependent squeeze-film damping[J]. Physical Review Applied, 19, 044005(2023).

[21] HUELLER M, CAVALLERI A, DOLESI R et al. Torsion pendulum facility for ground testing of gravitational sensors for LISA[J]. Classical and Quantum Gravity, 19, 1757-1765(2002).

[22] [22] HOLLINGTON D. The ge management system f LISA LISA Pathfinder[D]. London: Imperial College London, 2011.

[23] [23] Tongji University Department of Applied Mathematics. Higher Mathematics (Volume Two)[M]. 5th ed. Beijing: Higher Education Press, 2002.

[24] CAVALLERI A, CIANI G, DOLESI R et al. Increased Brownian force noise from molecular impacts in a constrained volume[J]. Physical Review Letters, 103, 140601(2009).

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Fang WANG, Ming-chao SHE, Xiao-dong PENG, Li'e QIANG, Peng XU, Wen-lin TANG, Yu-zhu ZHANG. Simulation of residual gas noise in high-precision inertial sensors with optical readout[J]. Chinese Optics, 2025, 18(3): 612

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Paper Information

Category: Special Column on Space-based Gravitational Wave Detection

Received: Oct. 8, 2024

Accepted: Dec. 17, 2024

Published Online: Jun. 16, 2025

The Author Email:

DOI:10.37188/CO.2024-0186

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