Persistent current and Wigner crystallization in a one dimensional quantum ring

Abstract

We use Density Functional Theory to study interacting spinless electrons on a one-dimensional quantum ring in the density range where the system undergoes Wigner crystallization. The Wigner transition leads to a drastic ``collective'' electron localization due to the Wigner crystal pinning, provided a weak impurity potential is applied. To reveal this localization we examine a persistent current in a ring penetrated by a magnetic flux. Using the DFT-OEP method we calculated the current as a function of the interaction parameter rS. We find that in the limit of vanishing impurity potential the persistent current stays constant up to a critical value of rSc=2.05 but shows a drastic exponential decay for larger rS which reflects a formation of a pinned Wigner crystal. Above rSc the amplitude of the electron density oscillations exactly follows the (rS-rSc)1/2 behaviour, confirming a second-order phase transition as expected in the mean-field-type OEP approximation.