Light-Induced Ferromagnetism in Moir\'e Superlattices

TL;DR

This paper demonstrates that optical excitation can induce and control ferromagnetic order in moiré superlattices of 2D materials, revealing a new way to dynamically tune many-body interactions and magnetic phases.

Contribution

It reports the discovery of light-induced ferromagnetism in WS2/WSe2 moiré superlattices, showing optical control of magnetic order via exciton-mediated exchange interactions.

Findings

Ferromagnetic hysteresis observed at specific doping levels.

Hysteresis persists down to charge neutrality.

Magnetic order can be optically tuned and controlled.

Abstract

Many-body interactions between carriers lie at the heart of correlated physics. The ability to tune such interactions would open the possibility to access and control complex electronic phase diagrams on demand. Recently, moir\'e superlattices formed by two-dimensional materials have emerged as a promising platform for quantum engineering such phenomena. The power of the moir\'e system lies in the high tunability of its physical parameters by tweaking layer twist angle, electrical field, moir\'e carrier filling, and interlayer coupling. Here, we report that optical excitation can drastically tune the spin-spin interactions between moir\'e trapped carriers, resulting in ferromagnetic order in WS2/WSe2 moir\'e superlattices over a small range of doping at elevated temperatures. Near the filling factor v = -1/3 (i.e., one hole per three moir\'e unit cells), as the excitation power at the exciton resonance increases, a well-developed hysteresis loop emerges in the reflective magnetic circular dichroism (RMCD) signal as a function of magnetic field, a hallmark of ferromagnetism. The hysteresis loop persists down to charge neutrality, and its shape evolves as the moir\'e superlattice is gradually filled, indicating changes of magnetic ground state properties. The observed phenomenon points to a mechanism in which itinerant photo-excited excitons mediate exchange coupling between moir\'e trapped holes. This exciton-mediated interaction can be of longer range than direct coupling between moir\'e trapped holes, and thus magnetic order can arise even in the dilute hole regime under optical excitation. This discovery adds a new and dynamic tuning knob to the rich many-body Hamiltonian of moir\'e quantum matter.