Order-by-disorder charge density wave condensation at q =(13,13,13) in kagome metal ScV6Sn6

Abstract

The recent discovery of a charge density wave order at the wave vector P (13,13,13) in the kagome metal ScV6Sn6 has created a mystery because subsequent theoretical and experimental studies show a dominant phonon instability instead at another wave vector H (13,13,12). In this paper, I use first principles total energy calculations to map out the landscape of the structural distortions due to the unstable phonon modes at H, L (12,0,12), and P present in this material. In agreement with previous results, I find that the distortions due to the H instability cause the largest gain in energy relative to the parent structure, followed in order by the L and P instabilities. However, only two distinct structure occur due to this instability, which are separated by 6 meV/f.u. The instability at L results in three distinct structures separated in energy by 5 meV/f.u. In contrast, six different distorted structures are stabilized due to the instability at P, and they all lie within 2 meV/f.u.\ of each other. Hence, despite a lower energy gain, the condensation at P could be favorable due to a larger entropy gain associated with the fluctuations within a manifold with larger multiplicity via the order-by-disorder mechanism.