Enhanced Magnetization by Defect-Assisted Exciton Recombination in Atomically Thin CrCl$_3$

Two dimensional (2D) semiconductors present unique opportunities to intertwine optical and magnetic functionalities and to tune these performances through defects and dopants. In 2D semiconductors, the properties of excitons often vary due to the underlying magnetic order, but the modification of their magnetic properties by excitonic processes remains difficult to achieve. Here, we integrate exciton pumping into a quantum sensing protocol on nitrogen-vacancy centers in diamond to image the optically-induced transient stray fields in few-layer, antiferromagnetic CrCl$_3$. We discover that exciton recombination enhances the in-plane magnetization of the CrCl$_3$ layers, with an outsized effect in the surface monolayers and when the surface is unencapsulated. Concomitantly, time-resolved photoluminescence measurements reveal that a defect-assisted Auger recombination dominates for atomically thin CrCl$_3$ with tightly localized, nearly forbidden excitons and amplified surface-to-volume ratio. These experimental signatures establish the magnetically enhanced state to result from an exciton-activated electron transfer between surface impurities and the spin-polarized conduction band. Density functional theory calculations identify that the mediating impurity state could originate from oxygen adsorbates with spins antiparallel to the magnetization of their host layer. Our work unambiguously demonstrates the tunability of single intrinsic magnetic layers via defect engineering and opens a pathway to dynamically reconfigure these effects in devices through optical control.