Intrinsic Chern Half-Metal with High Anomalous Hall Conductivity in 2D BaNiCl3

Abstract

Two-dimensional (2D) half-metals offer complete spin polarization at the Fermi level, making them candidates for dissipationless spin transport. Yet intrinsic 2D half-metals exhibiting robust topological features, particularly large Chern number anomalous Hall conductivities, remain exceptionally rare. Using first-principles calculations, we identify atomically thin BaNiCl3, a layered halide perovskite (perovskene), as a topological half-metal. It exhibits a high Chern number (C 2), a large anomalous Hall conductivity of 316~-1,cm-1, and a Fermi velocity of ≈ 0.78 × 106 m/s. The coexistence of complete spin polarization and high carrier velocity suggests low-dissipation spin transport. Spin-orbit coupling opens a sizable topological gap of 20\, meV, yielding nontrivial Berry curvature and enhancing the anomalous Hall response. Ferromagnetism is stabilized by the Ni2+ (d8) configuration and Cl-mediated superexchange, supporting magnetic ordering at elevated temperatures. These results establish BaNiCl3 as a rare intrinsic Chern half-metal, with potential applications in quantum and spintronic technologies.