Topological Magneto-Optical Effect and its Quantization in Noncoplanar Antiferromagnets

Magneto-optical (MO) effects have been known for more than a century as they reflect the basic interactions between light and magnetism. The origin of MO effects is usually ascribed to the simultaneous presence of band exchange splitting and spin-orbit coupling. Using a tight-binding model and first-principles calculations, we show that topological MO effects, in analogy to the topological Hall effect, can arise in noncoplanar antiferromagnets entirely due to the scalar spin chirality instead of spin-orbit coupling. The band exchange splitting is not required for topological MO effects. Moreover, we discover that the Kerr and Faraday rotation angles in two-dimensional insulating noncoplanar antiferromagnets can be quantized in the low-frequency limit, implying the appearance of quantum topological MO effects, accessible by time-domain THz spectroscopy.