Quantum Precision Limits of Displacement Noise-Free Interferometers

Creators: Gefen, Tuvia; Tarafder, Rajashik; Adhikari, Rana X.¹; Chen, Yanbei¹

1. California Institute of Technology

Abstract

Current laser-interferometric gravitational wave detectors suffer from a fundamental limit to their precision due to the displacement noise of optical elements contributed by various sources. Several schemes for displacement noise-free interferometers (DFI) have been proposed to mitigate their effects. The idea behind these schemes is similar to decoherence-free subspaces in quantum sensing; i.e., certain modes contain information about the gravitational waves but are insensitive to the mirror motion (displacement noise). We derive quantum precision limits for general DFI schemes, including optimal measurement basis and optimal squeezing schemes. We introduce a triangular cavity DFI scheme and apply our general bounds to it. Precision analysis of this scheme with different noise models shows that the DFI property leads to interesting sensitivity profiles and improved precision due to noise mitigation and larger gain from squeezing.

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Acknowledgement

The authors are thankful to J. Preskill, Y. Drori, E. D. Hall, K. Kuns, and L. McCuller for helpful discussions. T. G. acknowledges funding provided by the Institute for Quantum Information and Matter and the Quantum Science and Technology Scholarship of the Israel Council for Higher Education. Y. C. acknowledges the support by the Simons Foundation (Grant No. 568762). R. X. A. is supported by NSF Grants No. PHY-1764464 and No. PHY-191267.

Additional Information

SUPPLEMENTAL MATERIAL

Detailed derivation of the relevant quantum Fisher information matrix, optimal measurement basis, optimal squeezing, numerics of the polygon scheme, Calculation outline of the transfer matrices, Sagnac effect and comparison with standard Sagnac interferometers

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PhysRevLett.132.020801.pdf

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