Electric control of valley polarization in monolayer WSe 2 using a van der Waals magnet.
Jia-Xin LiWei-Qing LiSheng-Hsiung HungPo-Liang ChenYueh-Chiang YangTian-Yun ChangPo-Wen ChiuHorng-Tay JengChang-Hua LiuPublished in: Nature nanotechnology (2022)
Electrical manipulation of the valley degree of freedom in transition metal dichalcogenides is central to developing valleytronics. Towards this end, ferromagnetic contacts, such as Ga(Mn)As and permalloy, have been exploited to inject spin-polarized carriers into transition metal dichalcogenides to realize valley-dependent polarization. However, these materials require either a high external magnetic field or complicated epitaxial growth steps, limiting their practical applications. Here we report van der Waals heterostructures based on a monolayer WSe 2 and an Fe 3 GeTe 2 /hexagonal boron nitride ferromagnetic tunnelling contact that under a bias voltage can effectively inject spin-polarized holes into WSe 2 , leading to a population imbalance between ±K valleys, as confirmed by density functional theory calculations and helicity-dependent electroluminescence measurements. Under an external magnetic field, we observe that the helicity of electroluminescence flips its sign and exhibits a hysteresis loop in agreement with the magnetic hysteresis loop obtained from reflective magnetic circular dichroism characterizations on Fe 3 GeTe 2 . Our results could address key challenges of valleytronics and prove promising for van der Waals magnets for magneto-optoelectronics applications.