Electronic ordering driven by flat band nesting in a van der Waals magnet Fe5GeTe2
Abstract: Solid-state systems with flat electronic bands have a theoretical propensity to form electronic orders such as superconductivity and charge-density waves. However, for many flat-band systems such as Kagome and Clover lattices, the flat bands do not naturally appear at the Fermi level, hence not driving the low-energy electronic ordering. Here we demonstrate the concurrent formation of flat bands at the Fermi level and a $\sqrt{3} \times \sqrt{3}\, R30\circ$ charge order in a van der Waals magnet Fe5GeTe2 using high-resolution angle-resolved photoemission spectroscopy. This charge order is manifested by clear band structure folding below 100 K, yet the band folding is limited to 30 meV below the Fermi level where the flat bands reside. The nesting vector in the reciprocal space connects segments of Fermi surfaces where pronounced flat bands are discovered. Taken together with calculations of the Lindhard response function, our results establish Fe5GeTe2 as a model system where flat bands promote inter-band nesting and electronic ordering. The appearance of the flat band at the Fermi level is reminiscent of the Kondo lattice effect, yet we point out that the flat bands may originate from the abundance of vacancies in the Fe(1) sublattice, where the vacancies induce flat dispersions via destructive charge or spin interactions.
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