Related papers: Hybrid quantum network for sensing in the acoustic frequency range

Hybrid quantum network for sensing in the acoustic frequency range

URL: http://arxiv.org/abs/2412.11824v1
Date: Mon, 16 Dec 2024 14:45:44 GMT
Title: Hybrid quantum network for sensing in the acoustic frequency range
Authors: Valeriy Novikov, Jun Jia, Túlio Brito Brasil, Andrea Grimaldi, Maimouna Bocoum, Mikhail Balabas, Jörg Helge Müller, Emil Zeuthen, Eugene Simon Polzik,
Abstract summary: Applicability of quantum optical sensing is often restricted by fixed wavelengths of available photonic quantum sources. Here we demonstrate a novel tool for broadband quantum sensing by quantum state processing. We demonstrate frequency-dependent, entanglement-enabled quantum noise reduction for measurements at a disparate wavelength.
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Abstract: Ultimate limits for sensing of fields and forces are set by the quantum noise of a sensor. Entanglement allows for suppression of such noise and for achieving sensitivity beyond standard quantum limits. Applicability of quantum optical sensing is often restricted by fixed wavelengths of available photonic quantum sources. Another ubiquitous limitation is associated with challenges of achieving quantum-noise-limited sensitivity in the acoustic noise frequency range relevant for a number of applications. Here we demonstrate a novel tool for broadband quantum sensing by quantum state processing that can be applied to a wide range of the optical spectrum, and by suppressing quantum noise over an octave in the acoustic frequency range. An atomic spin ensemble in the quantum regime is strongly coupled to one of the tunable frequency modes of an Einstein-Podolsky-Rosen (EPR) source of light. The other EPR mode of light, entangled with the first one, is tuned to a disparate wavelength. Engineering the spin ensemble to act as a negative- or positive-mass oscillator we demonstrate frequency-dependent, entanglement-enabled quantum noise reduction for measurements at the disparate wavelength. The tunability of the spin ensemble allows to target quantum noise in a variety of systems with dynamics ranging from kHz to MHz. As an example of the broadband quantum noise reduction in the acoustic frequency range, we analyse the applicability of our approach to state-of-the-art gravitational wave detectors. Other possible applications include continuous-variable quantum repeaters and distributed quantum sensing.

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