Surpassing the Standard Quantum Limit Using an Optical Spring

Quantum mechanics places noise limits and sensitivity restrictions on physical measurements. The balance between unwanted backaction and the precision of optical measurements imposes a standard quantum limit (SQL) on interferometric systems. In order to realize a sensitivity below the SQL, it is nec...

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Veröffentlicht in:Physical review letters 2024-09, Vol.133 (11), p.113602, Article 113602
Hauptverfasser: Cullen, Torrey, Pagano, Ronald, Aronson, Scott, Cripe, Jonathan, Sharif, Sarah Safura, Lollie, Michelle, Cain, Henry, Heu, Paula, Follman, David, Cole, Garrett D, Aggarwal, Nancy, Corbitt, Thomas
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Sprache:eng
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Zusammenfassung:Quantum mechanics places noise limits and sensitivity restrictions on physical measurements. The balance between unwanted backaction and the precision of optical measurements imposes a standard quantum limit (SQL) on interferometric systems. In order to realize a sensitivity below the SQL, it is necessary to leverage a backaction evading measurement technique, reduce thermal noise to below the level of backaction, and exploit cancellations of any excess noise contributions at the detector. Many proof of principle experiments have been performed, but only recently has an experiment achieved sensitivity below the SQL. In this work, we extend that initial demonstration and realize sub-SQL sensitivity nearly two times better than previous measurements, and with an architecture applicable to interferometric gravitational wave detectors. In fact, this technique is directly applicable to Advanced LIGO, which could observe similar effects with a detuned signal recycling cavity. We measure a total sensitivity below the SQL by 2.8 dB, corresponding to a reduction in the noise power by 72±5.1% below the quantum limit. Through the use of a detuned cavity and the optical spring effect, this noise reduction is tunable, allowing us to choose the desired range of frequencies that fall below the SQL. This result demonstrates access to sensitivities well below the SQL at frequencies applicable to LIGO, with the potential to extend the reach of gravitational wave detectors further into the Universe.
ISSN:0031-9007
1079-7114
1079-7114
DOI:10.1103/PhysRevLett.133.113602