Antiferromagnetic Dimers in the Parent Phase of a Correlated Kagome Superconductor

Abstract

Kagome metals are prone to charge-density wave (CDW), magnetic, and superconducting phases, with their flat electronic band conducive for correlated physics. In contrast to the weakly correlated AV3Sb5 (A = K, Rb, Cs) kagome metals with a 2×2 CDW, CsCr3Sb5 is a correlated metal with a flat band close to the Fermi level, and exhibits a 4×1 CDW intertwined with magnetic order. Under pressure, the intertwined orders are suppressed and give way to a dome of superconductivity that emerges from a non-Fermi liquid normal state. Here, we solve the crystal structure of the 4× 1 CDW state in CsCr3Sb5, and show it consists of Cr dimers separated by Cr chains. First-principles calculations show the dominant exchange interaction is antiferromagnetic within the dimers, while the intra-chain and dimer-chain couplings are much weaker. The CDW transition of CsCr3Sb5 is found to be more strongly first-order than those in AV3Sb5, without significant soft phonons or diffuse scattering above the CDW transition temperature. These findings suggest that fluctuating antiferromagnetic dimers may play a major role in the electron pairing of superconducting CsCr3Sb5.