Long-ranged charge order conspired by magnetism and lattice in an antiferromagnetic Kagome metal

Abstract

Abstract Exotic quantum states could be induced due to the interplay of various degrees of freedom such as charge, spin, orbital, and lattice. Recently, a novel short-ranged charge order (CO) was discovered deep inside the antiferromagnetic phase of a correlated Kagome magnet FeGe. Since the spin-polarization is significantly enhanced in the CO state, magnetism may play an important role. However, its short-ranged nature hinders the precise identification of CO properties, and its mechanism is still controversial. Here, we report the observation of a long-ranged CO in high-quality FeGe samples, in contrast to the previously reported short-ranged ones. Moreover, the distorted 2 ×2×2 CO superstructure can now be precisely refined, which is characterized by a strong dimerization along the c-axis of 1/4 of the Ge1-sites in the Fe3Ge layers. Our results provide strong support to the recent theoretical prediction (arXiv:2304.01604), where the CO in FeGe is driven by saving magnetic exchange energies via such dimerization. Consequently, the enhancement of spin-polarization and the previously observed short-ranged CO can be understood. Our experiments, combined with the theory, have provided a comprehensive understanding of the puzzling CO behavior in FeGe, and established a novel charge order mechanism conspired by magnetism and lattice, different from conventional charge density wave mechanisms.