TY - JOUR
T1 - Highly Efficient Nonvolatile Magnetization Switching and Multi-Level States by Current in Single Van der Waals Topological Ferromagnet Fe3GeTe2
AU - Zhang, Kaixuan
AU - Lee, Youjin
AU - Coak, Matthew J.
AU - Kim, Junghyun
AU - Son, Suhan
AU - Hwang, Inho
AU - Ko, Dong-Su
AU - Oh, Youngtek
AU - Jeon, Insu
AU - Kim, Dohun
AU - Zeng, Changgan
AU - Lee, Hyun-Woo
AU - Park, Je-Geun
PY - 2021/12/2
Y1 - 2021/12/2
N2 - Robust multi-level spin memory with the ability to write information electrically is a long-sought capability in spintronics, with great promise for applications. Here, nonvolatile and highly energy-efficient magnetization switching is achieved in a single-material device formed of van-der-Waals (vdW) topological ferromagnet Fe3GeTe2, whose magnetic information can be readily controlled by a tiny current. Furthermore, the switching current density and power dissipation are about 400 and 4000 times smaller than those of the existing spin-orbit-torque magnetic random access memory based on conventional magnet/heavy-metal systems. Most importantly, multi-level states, switched by electrical current are also demonstrated, which can dramatically enhance the information capacity density and reduce computing costs. Thus, the observations combine both high energy efficiency and large information capacity density in one device, showcasing the potential applications of the emerging field of vdW magnets in the field of spin memory and spintronics.
AB - Robust multi-level spin memory with the ability to write information electrically is a long-sought capability in spintronics, with great promise for applications. Here, nonvolatile and highly energy-efficient magnetization switching is achieved in a single-material device formed of van-der-Waals (vdW) topological ferromagnet Fe3GeTe2, whose magnetic information can be readily controlled by a tiny current. Furthermore, the switching current density and power dissipation are about 400 and 4000 times smaller than those of the existing spin-orbit-torque magnetic random access memory based on conventional magnet/heavy-metal systems. Most importantly, multi-level states, switched by electrical current are also demonstrated, which can dramatically enhance the information capacity density and reduce computing costs. Thus, the observations combine both high energy efficiency and large information capacity density in one device, showcasing the potential applications of the emerging field of vdW magnets in the field of spin memory and spintronics.
KW - magnetization switching
KW - multi-level states
KW - spintronics
KW - spin-orbit-torque-based memory
KW - topological magnetic van der Waals Fe 3GeTe 2
U2 - 10.1002/adfm.202105992
DO - 10.1002/adfm.202105992
M3 - Article
SN - 1616-301X
VL - 31
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 49
M1 - 2105992
ER -