Litcius/Paper detail

Floquet Quantum Anomalous Hall Effect with In-Plane Magnetization in Two-Dimensional Altermagnets

Xiaorong Zou, Xiaoran Feng, Ying Dai, Baibiao Huang, Chengwang Niu

2025ACS Nano17 citationsDOI

Abstract

Altermagnets and the quantum anomalous Hall effect (QAHE) are intrinsically important for advancing low-dissipation spintronics. However, the emergence of QAHE in altermagnets remains elusive. Here, we realize the Floquet QAHE in a 2D altermagnet with in-plane magnetization and, in particular, put forward that Floquet–Bloch band engineering drives a topological phase transition from the second-order topological insulator (SOTI) to a QAH insulator. Taking the square lattice as an example, the Janus V 2 XTeO (X = Se and S) monolayers are investigated as the potential systems to access the viability of the proposed scheme. The Janus V 2 XTeO monolayers are prototypical materials for altermagnets, and without light irradiation, they are SOTIs distinguished by nontrivial corner states. Driven by a time-periodic optical field, engineered light intensity triggers the topological phase transition that gives rise to QAHE, concurrently evidenced by a quantized Chern number of C = 1 and a chiral edge state. These findings demonstrate the exotic QAHE in altermagnets, providing a prototype platform for intrinsic topological phenomena that is expected to draw great experimental attention.

Topics & Concepts

Quantum anomalous Hall effectFloquet theoryCondensed matter physicsTopological insulatorPhysicsMagnetizationQuantumQuantum Hall effectJanusTopological orderMonolayerTopology (electrical circuits)Phase transitionLattice (music)Square latticeElectronic band structurePhase (matter)Quantum phase transitionChern classHall effectQuantum spin Hall effectGeometric phaseMaterials scienceQuantum mechanicsVisible spectrumQuantum opticsOptoelectronicsKubo formulaTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsAtomic and Subatomic Physics Research