Persistent current of SU(N) fermions

We study the persistent current in a system of SU(N) fermions with repulsive interaction, confined in a ring-shaped potential and pierced by an effective magnetic flux. Several surprising effects emerge. As a combined result of spin correlations, (effective) magnetic flux and interaction, spinons can be created in the ground state such that the elementary flux quantum can change its nature. The persistent current landscape is affected dramatically by these changes. In particular, it displays a universal behaviour. Despite its mesoscopic character, the persistent current is able to detect a quantum phase transition (from metallic to Mott phases). Most of, if not all, our results could be experimentally probed within the state-of-the-art quantum technology, with neutral matter-wave circuits providing a particularly relevant platform for our work.

Automated summary

We study the persistent current in a system of SU(N) fermions with repulsive interaction. We find surprising effects, where spinons can be created and change the nature of the elementary flux quantum due to spin correlations, (effective) magnetic flux, and interaction. These changes have a dramatic impact on the persistent current and can detect quantum phase transitions.