Magneto-strain effects in 2D ferromagnetic van der Waal material CrGeTe3

The idea of strain based manipulation of spins in magnetic two-dimensional (2D) van der Waal (vdW) materials leads to the development of new generation spintronic devices. Magneto-strain arises in these materials due to the thermal fluctuations and magnetic interactions which influences both the lattice dynamics and the electronic bands. Here, we report the mechanism of magneto-strain effects in a vdW material CrGeTe3 across the ferromagnetic (FM) transition. We find an isostructural transition in CrGeTe3 across the FM ordering with first order type lattice modulation. Larger in-plane lattice contraction than out-of-plane give rise to magnetocrystalline anisotropy. The signature of magneto-strain effects in the electronic structure are shift of the bands away from the Fermi level, band broadening and the twinned bands in the FM phase. We find that the in-plane lattice contraction increases the on-site Coulomb correlation (U-eff) between Cr atoms resulting in the band shift. Out-of plane lattice contraction enhances the d - p hybridization between Cr-Ge and Cr-Te atoms which lead to band broadening and strong spin-orbit coupling (SOC) in FM phase. The interplay between U(eff )and SOC out-of-plane gives rise to the twinned bands associated with the interlayer interactions while the in-plane interactions gives rise to the 2D spin polarized states in the FM phase.

Automated summary

The idea of manipulating spins in magnetic two-dimensional van der Waal materials through strain has led to the development of new generation spintronic devices. Magneto-strain effects arise due to thermal fluctuations and magnetic interactions, influencing the lattice dynamics and electronic bands. In this study, the mechanism of magneto-strain effects in CrGeTe3, a vdW material, across the ferromagnetic transition is investigated. It is found that an isostructural transition occurs in CrGeTe3 with lattice modulation during the ferromagnetic ordering. The in-plane lattice contraction leads to magnetocrystalline anisotropy, while the electronic structure exhibits band shifts, broadening, and twinned bands in the ferromagnetic phase.