Optical Spin Sensing and Metamagnetic Phase Control in the 2D Van der Waals Magnet Yb3+-Doped CrPS4

Abstract

The emergence of two-dimensional magnets within the van der Waals toolkit has introduced unprecedented opportunities to develop ultrathin spintronic technologies. Strong coupling between spin and optical properties in such materials can further enable novel spin-photonic capabilities of both fundamental and technological interest. Here, we investigate the optical and spin properties of the air-stable, layered A-type antiferromagnet chromium thiophosphate (CrPS4) when doped with Yb3+. We show that the collective spin properties of CrPS4 are encoded in the sharp f-f luminescence of isolated Yb3+ dopants via strong magnetic superexchange coupling between the two, and that spontaneous magnetic ordering in CrPS4 induces large exchange splittings in the narrow Yb3+ f-f photoluminescence features below TN. Spin reorientation in CrPS4 via a "spin-flop" metamagnetic transition modulates the Yb3+ f-f luminescence energies and exchange splittings. This pronounced link between spin and optical properties enables the demonstration of optically driven spin-flop transitions in CrPS4.