Charge Density Wave Coexisting with Amplified Nematicity in the Correlated Kagome Metal CsCr3Sb5

Abstract: The correlated phenomena of flat bands have been extensively studied in twisted systems. However, the emergent ordered states arising from interactions in intrinsic multi-orbital flat bands in kagome lattice materials remain largely unexplored. In contrast to the vanadium-based AV3Sb5 (A = K, Rb, Cs), the newly discovered kagome metal CsCr3Sb5, featuring pressurized superconductivity, antiferromagnetism, structural phase transition, and density wave orders, provides a rich platform for investigating strong electron correlations in multi-orbital flat bands at the Fermi surface. Here, using ultrafast optical techniques, we reveal the gap opening and the emergence of a distinct 1x4 charge density wave (CDW) at low temperatures in CsCr3Sb5. We also find that this CDW reduces the rotational symmetry to three inequivalent nematic domains, and the exotic nematicity is further amplified by the degeneracy lifting of the multi-orbital flat bands, similar to some iron-based superconductors. Surprisingly, both CDW and orbital nematicity appear concurrently with spin and structural orders at the same temperature, indicating that a single characteristic energy scale governs the low-energy flat band physics. Our study thus pioneers the investigation of ultrafast dynamics in flat band systems at the Fermi surface, offering new insights into the interactions between multiple elementary excitations in strongly correlated systems.