Strain- and Field-Tunable Nonrelativistic Spin Splitting and Wave-Symmetry-Dependent Spin Transport in Twisted Bilayer Altermagnets

Abstract

Magnetism-driven nonrelativistic spin splitting (NRSS) provides a pathway toward efficient, spin-orbit-free spintronics. In centrosymmetric two-dimensional antiferromagnets, spin-polarized transport is symmetry-forbidden due to the combined space-time inversion (PT) symmetry. Here, by employing first-principles density functional theory and spin-group symmetry analysis, we demonstrate that twisting two antiferromagnetic or ferromagnetic monolayers of CoCl2, AX2 (A = Mn, V; X = Cl, Br, I), NiF2, NiBr2, FeS, CoS, MnTe2, MnSe2, and RuSe induces finite NRSS even in the absence of spin-orbit coupling. The relative twist breaks [C2||P] and [E||Cnz] symmetries, giving rise to momentum-dependent spin polarization with distinct d-, g-, and i-wave altermagnetic patterns across the Brillouin zone. Using symmetry-invariant k· p modeling, we extract linear spin-splitting coefficients α(1) ranging from 800-1100 meV, comparable to SOC-induced Rashba-Dresselhaus strengths observed in noncentrosymmetric semiconductors. An out-of-plane electric field (Ez) introduces Zeeman-type band splitting up to 110 meV at 10 MV/cm, while biaxial strain tunes the NRSS magnitude nearly linearly without altering symmetry. Crucially, the strain uxx-yy reduces the spin point group symmetry and drives reversible g/i → d wave-type transitions, resulting in finite spin conductivity and an enhanced spin-splitter angle (up to 18). These results extend the concept of altermagnetism to twisted bilayer geometries and establish a general route for realizing exchange-driven, nonrelativistic spin currents through symmetry engineering without requiring heavy elements or spin-orbit coupling.