Feedback cooling of the normal modes of a massive electromechanical system to submillikelvin temperature

A. Ortolan; A. Vinante; F. Salemi; G.A. Prodi; G. Vedovato; J.-P. Zendri; L. Conti; L. Taffarello; M. Bignotto; M. Bonaldi

arxiv: 0803.0470 · v3 · submitted 2008-03-04 · 🪐 quant-ph

Feedback cooling of the normal modes of a massive electromechanical system to submillikelvin temperature

A. Vinante , M. Bignotto , M. Bonaldi , M. Cerdonio , L. Conti , P. Falferi , N. Liguori , S. Longo

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R. Mezzena A. Ortolan G.A. Prodi F. Salemi L. Taffarello G. Vedovato S. Vitale J.-P. Zendri

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keywords temperaturecoolingfeedbacknormalquantumsquidbathelectromechanical

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We apply a feedback cooling technique to simultaneously cool the three electromechanical normal modes of the ton-scale resonant-bar gravitational wave detector AURIGA. The measuring system is based on a dc Superconducting Quantum Interference Device (SQUID) amplifier, and the feedback cooling is applied electronically to the input circuit of the SQUID. Starting from a bath temperature of 4.2 K, we achieve a minimum temperature of 0.17 mK for the coolest normal mode. The same technique, implemented in a dedicated experiment at subkelvin bath temperature and with a quantum limited SQUID, could allow to approach the quantum ground state of a kilogram-scale mechanical resonator.

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