Giant spin shift current in two-dimensional altermagnetic multiferroics VOX$\mathrm{_2}$ (2503.13140v5)

Abstract: Altermagnets represent a novel class of magnetic materials that integrate the advantages of both ferromagnets and antiferromagnets, providing a rich platform for exploring the physical properties of multiferroic materials.This work demonstrates that $\mathrm{VOX_2}$ monolayers ($\mathrm{X = Cl, Br, I}$) are two-dimensional ferroelectric altermagnets, as confirmed by symmetry analysis and first-principles calculations. $\mathrm{VOI_2}$ monolayer exhibits a strong magnetoelectric coupling coefficient ($\alpha_S \approx 1.208 \times 10^{-6}~\mathrm{s/m}$), with spin splitting in the electronic band structure tunable by both electric and magnetic fields. Additionally, the absence of inversion symmetry in noncentrosymmetric crystals enables significant nonlinear optical effects, such as shift current (SC). The $x$-direction component of SC exhibits a ferroicity-driven switching behavior. Moreover, the $\sigma^{yyy}$ component exhibits an exceptionally large spin SC of $330.072~\mathrm{\mu A/V^2}$. These findings highlight the intricate interplay between magnetism and ferroelectricity, offering versatile tunability of electronic and optical properties. $\mathrm{VOX_2}$ monolayers provide a promising platform for advancing two-dimensional multiferroics, paving the way for energy-efficient memory devices, nonlinear optical applications and opto-spintronics.