First-order Bose-Einstein condensation with three-body interacting bosons
Abstract
Bose-Einstein condensation, observed in either strongly interacting liquid helium or weakly interacting atomic Bose gases, is widely known to be a second-order phase transition. Here, we predict a first-order Bose-Einstein condensation in a cloud of harmonically trapped bosons interacting with both attractive two-body interaction and repulsive three-body interaction, characterized respectively by an -wave scattering length and a three-body scattering hypervolume . It happens when the harmonic trapping potential is weak, so with increasing temperature the system changes from a low-temperature liquid-like quantum droplet to a normal gas, and therefore experiences a first-order liquid-to-gas transition. At large trapping potential, however, the quantum droplet can first turn into a superfluid gas, rendering the condensation transition occurred later from a superfluid gas to a normal gas smooth. We determine a rich phase diagram and show the existence of a tri-critical point, where the three phases - quantum droplet, superfluid gas and normal gas - meet together. We argue that an ensemble of spin-polarized tritium atoms could be a promising candidate to observe the predicted first-order Bose-Einstein condensation, across which the condensate fraction or central condensate density jumps to zero and the surface-mode frequencies diverge.
Cite
@article{arxiv.2103.16044,
title = {First-order Bose-Einstein condensation with three-body interacting bosons},
author = {Hui Hu and Zeng-Qiang Yu and Jia Wang and Xia-Ji Liu},
journal= {arXiv preprint arXiv:2103.16044},
year = {2022}
}
Comments
14 pages, 7 figures