Anomalous spin-lattice coupling in a 2D antiferromagnetic semiconductor revealed by surface acoustic Rayleigh waves

TL;DR

This study reveals a giant magnetoelastic effect in a 2D antiferromagnetic semiconductor, NiPS3, where magnetic order significantly alters surface acoustic phonon velocities, demonstrating the interplay between magnetism and lattice dynamics.

Contribution

It provides the first experimental observation and theoretical analysis of surface acoustic wave anomalies across the magnetic transition in a 2D antiferromagnetic material.

Findings

Surface Rayleigh wave velocity softens by 5.5% below Neel temperature.

Giant magnetoelastic renormalization of elastic constants occurs due to magnetic order.

First-principles calculations match experimental dispersion and shifts.

Abstract

Magnetic order in van der Waals magnets can strongly influence their lattice dynamics, yet how this interaction manifests across different phonon length scales remains unclear. Optical phonons probe bond-scale exchange modulation and short-range spin correlations, whereas long-wavelength acoustic modes couple to uniform strain fields and are sensitive to the renormalization of the macroscopic elastic tensor associated with long-range magnetic order. Experimentally accessing these low-energy acoustic excitations in low-dimensional crystals is challenging due to their low energies and the small lateral dimensions of exfoliated samples. Here, we employ angle-resolved Brillouin-Mandelstam scattering spectroscopy to investigate the surface acoustic phonon spectrum of exfoliated NiPS3 thin films across their antiferromagnetic transition temperature. Our results show a single Rayleigh surface mode whose phase velocity exhibits a pronounced 5.5% softening upon cooling through the Neel temperature. This anomaly reflects a giant magnetoelastic renormalization of the long-wavelength elastic constants triggered by the onset of zigzag antiferromagnetic order. First-principles calculations of the full elastic tensor, combined with continuum finite-element modelling of the NiPS3/SiO2/Si heterostructure, reproduce both the Rayleigh-wave dispersion and its magnetic-order-induced shift. The obtained results reveal how microscopic exchange interactions shape macroscopic mechanical properties in two-dimensional antiferromagnetic semiconductors, providing a basis for lattice-controlled magnetism and magnetically tunable phononic, magnonic, and strain-mediated spintronic device concepts.