📝 SummarXiv

Abstract

In a recent experiment [arXiv:2508.21311] the long-sought dice lattice and its characteristic flat band has been discovered for the first time in the two-dimensional layered electride yttrium monochloride (YCl), in which the interstitial anionic electrons of the electride self-organize into a dice lattice geometry. In this Letter, combining symmetry analysis, relativistic density-functional theory and realistic tight-binding model calculations, we predict that the dice flat band in YCl is intrinsically topological and characterized by a high Chern number of $\mathcal{C} = \pm 4$. In particular, the intrinsic atomic spin-orbit coupling (SOC) from $4d$-electrons of yttrium atoms creates topological gaps on the scale of 20 meV near $\pm K$ and leads to the emergence of nontrivial Berry curvatures and band topology. Displacement fields applied across the layered electride architecture can easily drive topological phase transitions. Our findings establish the newly discovered YCl electride as the first natural material hosting a dice flat Chern band without any extrinsic band engineering.