Phase-Dependent Magnetic Proximity Modulations on Valley Polarization and Splitting
Jin’an Li, Zilong Chen, Jiangpeng Zhou, Yiteng Zhang, Xu Li, Zhiming Wu, Yaping Wu, Junyong Kang
Abstract
Proximate-induced magnetic interactions present a promising strategy for precise manipulation of valley degrees of freedom. Taking advantage of the splendid valleytronic platform of transition metal dichalcogenides, magnetic two-dimensional VSe 2 with different phases are introduced to intervene in the spin of electrons and modulate their valleytronic properties. When constructing the heterostructures, 1T-VSe 2 /WX 2 (X = S and Se) showcases significant improvement in the valley polarizations at room temperature, while 2H-VSe 2 /WX 2 exhibits superior performance at low temperatures and demonstrates heightened sensitivity to the external magnetic field. Simultaneously, considerable valley splitting with a large g eff factor up to −29.0 is observed in 2H-VSe 2 /WS 2, while it is negligible in 1T-VSe 2 /WX 2 . First-principles calculations reveal a phase-dependent magnetic proximity mechanism on the valleytronic modulations, which is dominated by interfacial charge transfer in 1T-VSe 2 /WX 2 and the proximity exchange field in 2H-VSe 2 /WX 2 heterostructures. The effective control over valley degrees of freedom will bridge the valleytronic physics and devices, rendering enormous potential in the field of valley quantum applications.