Ferroelectric Control of Polarity of the Spin‐polarized Current in Van Der Waals Multiferroic Heterostructures
Xiwen Zhang, Zhaobo Zhou, Xing Yu, Yilv Guo, Yunfei Chen, Jinlan Wang
Abstract
Abstract Ferroelectric (FE) control of magnetism at nanoscale, for instance, FE control of the polarity of spin‐polarized current is crucial for technological advances in magnetoelectric and spintronic applications. However, this fascinating functionality has not been reported in nanoscale systems yet. Herein, a new class of FE/A‐type antiferromagnetic heterobilayer/FE van der Waals (vdW) multiferroic structures is found, in which the FE control of polarity of spin‐polarized current is found possible. Take Sc 2 CO 2 /CrSiTe 3 /CrGeTe 3 /Sc 2 CO 2 heterostructure as a successful example. First‐principles calculations reveal that its polarity of half‐metallicity can be switched by flipping the FE polarization orientation. Meanwhile, device transport simulation shows that its up/down spin current transmission ratio is as large as 0.1 × 10 3 at Sc 2 CO 2 configuration and is only 2.6 × 10 −3 at Sc 2 CO 2 configuration in the vdW multiferroic heterostructures. Essentially, it stems from the reversible FE switch of the internal electric field across the CrSiTe 3 /CrGeTe 3 heterobilayer and the FE control of the interfacial effect between Sc 2 CO 2 and Cr(Si/Ge)Te 3 layers. This work opens a direction for constructing low‐energy‐dissipation, non‐volatile, and high‐sensitive spintronic devices such as spin field‐effect transistors.