Realization of an all-optical effective negative-mass oscillator for coherent quantum noise cancellation
- URL: http://arxiv.org/abs/2511.08056v1
- Date: Wed, 12 Nov 2025 01:37:08 GMT
- Title: Realization of an all-optical effective negative-mass oscillator for coherent quantum noise cancellation
- Authors: Nived Johny, Jonas Junker, Bernd Schulte, Dennis Wilken, Klemens Hammerer, Michèle Heurs,
- Abstract summary: coherent quantum noise cancellation (CQNC) scheme offers a broadband cancellation capability with a tunable, wavelength-flexible, and compact system.<n>We project a broadband quantum noise reduction of 3.6 dB, corresponding to a 77% reduction in quantum back-action noise at the optimal frequency of maximum reduction.<n>We discuss the prospects for new applications in quantum information and communication using the same platform.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We report the realization of an all-optical, tabletop effective-negative-mass oscillator (ENMO) scheme capable of canceling quantum noise when cascaded with an opto-mechanical sensor susceptible to (quantum) radiation pressure noise. Our coherent quantum noise cancellation (CQNC) scheme offers a broadband cancellation capability with a tunable, wavelength-flexible, and compact system. This is achieved through the implementation of an optical equivalent of an opto-mechanical interaction, facilitated by a down-conversion and a beam-splitting process. The intricate nature of the system and its multiple interacting components made characterizing the interdependent parameters with conventional methods ineffective, leading to the development of an in-situ characterization scheme. The obtained parameters meet the targets for CQNC set in previous studies. With our current realization, we project a broadband quantum noise reduction of 3.6 dB, corresponding to a 77% reduction in quantum back-action noise at the optimal frequency of maximum reduction, indicating the readiness of the ENMO for application. We discuss the prospects for new applications in quantum information and communication using the same platform.
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