Microscopic nature of the charge-density wave in kagome superconductor RbV3Sb5

Abstract

The recently discovered vanadium-based kagome metals AV3Sb5 (A = K, Rb, Cs) offer the possibility to study the interplay between competing electronic orderings, such as charge density order and superconductivity. We focus on the former and provide a comprehensive set of 51V, 87Rb, and 121Sb magnetic resonance measurements on an RbV3Sb5 single crystal. Elucidating the symmetries and properties of the CDW phase is essential to understanding the unconventional electronic orderings occurring in this material. We establish the structure of the 2× 2 × 2 superlattice that describes the system below the charge density wave transition by combining both experimental and computational methods, with a methodology that can be readily applied to the remaining compounds of the same family. Our results give compelling evidence that the CDW structure occurring below 103 K for RbV3Sb5 is the so-called Inverse Start of David pattern π-shifted along the c axis (also known as staggered tri-hexagonal).