Berry curvature dipole and nonlinear Hall effect in two-dimensional Nb2n+1SinTe4n+2

Abstract

Recent experiments have demonstrated interesting physics in a family of two-dimensional (2D) composition-tunable materials Nb2n+1SinTe4n+2. Here, we show that owing to its intrinsic low symmetry, metallic nature, tunable composition, and ambient stability, these materials offer a good platform for studying Berry curvature dipole (BCD) and nonlinear Hall effect. Using first-principles calculations, we find that BCD exhibits pronounced peaks in monolayer Nb3SiTe6 (n=1 case). Its magnitude decreases monotonically with n and completely vanishes in the n→∞ limit. This variation manifests a special hidden dimensional crossover of the low-energy electronic states in this system. The resulting nonlinear Hall response from BCD in these materials is discussed. Our work reveals pronounced geometric quantities and nonlinear transport physics in Nb2n+1SinTe4n+2 family materials, which should be readily detected in experiment.