Unconventional interplay between charge density wave order and superconductivity in the AV3Sb5 (A=K, Rb, Cs) class of topological kagome metals

Compounds built from quasi-two dimensional kagome networks of metal ions have long been of interest due to their potential for realizing a broad array of anomalous electronic states, ranging from quantum spin liquid phases to unconventional superconducting states.  More recently, kagome metals have come into focus as compelling platforms featuring an interplay between topologically nontrivial electronic states and correlated electron phenomena.  This interplay is naively realized via presence of an interference-driven flat band, Dirac points, as well as multiple van Hove singularities native to the band structure of the kagome network. An enduring challenge is to identify these states in real materials, and, in this talk, I will present recent work exploring the AV3Sb5 (A=K, Rb, Cs) class of kagome metals.  These compounds are Z2 topological metals with a band filling close to the kagome network's van Hove singularities, and they realize charge density wave order as well as a lower temperature superconducting ground state.  The unconventional properties of the charge density wave state and how it intertwines with superconducting order will be presented, and open questions and future directions will be discussed.

Zoom recording link