Enhancement of Wigner crystallization in quasi-low-dimensional solids

The crystallization of electrons in quasi-low-dimensional solids is studied in a model that retains the full three-dimensional nature of the Coulomb interactions. We show that restricting the electron motion to layers (or chains) gives rise to a rich sequence of structural transitions upon varying the particle density. In addition, the concurrence of low-dimensional electron motion and isotropic Coulomb interactions leads to a sizable stabilization of the Wigner crystal, which could be one of the mechanisms at the origin of the charge-ordered phases frequently observed in such compounds. The crystallization of electrons in quasi-low-dimensional solids is studied in a model that retains the full three-dimensional nature of the Coulomb interactions. We show that restricting the electron motion to layers (or chains) gives rise to a rich sequence of structural transitions upon varying the particle density. In addition, the concurrence of low-dimensional electron motion and isotropic Coulomb interactions leads to a sizable stabilization of the Wigner crystal, which could be one of the mechanisms at the origin of the charge-ordered phases frequently observed in such compounds.