The miscibility condition for a binary mixture of two interacting Bose-Einstein condensates is shown to be deeply affected by interaction driven thermal fluctuations. These give rise to a first order phase transition to a demixed phase with full spatial separation of the two condensates, even if the mixture is miscible at zero temperature. Explicit predictions for the isothermal compressibility, the spin susceptibility, and the phase transition temperature T-M are obtained in the framework of Popov theory, which properly includes beyond mean-field quantum and thermal fluctuations in both the spin and density channels. For a mixture of two sodium condensates occupying the hyperfine states vertical bar F = 1 >, vertical bar m(F) = 1 > and vertical bar F = 1, m(F) = -1 >, respectively, T-M is predicted to occur at about 0.7 times the usual BEC critical temperature.
Magnetic Phase Transition in a Mixture of Two Interacting Superfluid Bose Gases at Finite Temperature
Giorgini Stefano;Stringari Sandro
2019
Abstract
The miscibility condition for a binary mixture of two interacting Bose-Einstein condensates is shown to be deeply affected by interaction driven thermal fluctuations. These give rise to a first order phase transition to a demixed phase with full spatial separation of the two condensates, even if the mixture is miscible at zero temperature. Explicit predictions for the isothermal compressibility, the spin susceptibility, and the phase transition temperature T-M are obtained in the framework of Popov theory, which properly includes beyond mean-field quantum and thermal fluctuations in both the spin and density channels. For a mixture of two sodium condensates occupying the hyperfine states vertical bar F = 1 >, vertical bar m(F) = 1 > and vertical bar F = 1, m(F) = -1 >, respectively, T-M is predicted to occur at about 0.7 times the usual BEC critical temperature.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
