Beyond the Octupole Approximation in Non-Collinear Antiferromagnetic Thin Films (2505.07489v1)

Abstract: Noncollinear antiferromagnets offer much promise for antiferromagnetic spintronics and neuromorphic applications with a plethora of functional properties surpassing many competing magnetic systems. Films grown on mismatched substrates can relieve strain by the creation of slip-plane defects - and recently we have shown that these defects can manipulate global physical properties important for application. Here we demonstrate that post growth annealing results in near-defect-free, structurally robust films that allow the magnetic order thermal evolution to change as a function of film thickness. Strong spin-lattice coupling ensures that substrate clamping limits the ability of thinner films to transform as they are cooled to low temperature. However, beyond a certain thickness, films no longer suffer this constraint, revealing the extraordinary transformations that provide the pathway for spin to reach the lowest energy state. We show that this transition cannot be explained by the previously established mechanism of spin rotations in the (111) plane, and we calculate that rotations along the chirality-inverting [1-10] direction may be preferable under certain conditions. Our work suggests that chirality inverting rotations in these materials may have been previously overlooked in studies adopting the so-called octupole approximation of the net magnetic moment. This enriches the field of antiferromagnetic spintronics, raising the possibility of device designs with thickness engineered to exploit switching of chirality.