Quantum fluids, Josephson tunneling and gravitational waves
Résumé
In this paper we study the Josephson tunneling for a quantum fluid (a Bose-Einstein condensate) in presence of a weak gravitational wave. Starting from a lagrangian formulation in the framework of linearized gravity, we deduce the Gross-Pitaevskii equation for the fluid in a weak gravitational background. We use such equation to investigate the influence of a gravitational wave on Josephson effect. Considering a double-well trap, made of two identical boxes placed orthogonally each other and weakly coupled through a small junction, we show how the trap geometry influences the coupling between the gravitational wave and the quantum field modes in the two sides of the trap. Namely, the macroscopic wavefunction of the condensate acquires a different phase shift in the two sides, hence giving rise to a gravitationally-induced ac-Josephson effect through the trap junction. Although small, such effect is theoretically interesting, since it represents the influence of a gravitational wave on a mesoscopic quantum system. Also, the effect exhibits polarimetric properties. Possible experimental detection of such effect is briefly discussed at the end of the paper.
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