Tuning the Magnetic Properties of CrI3 Using Ni Thin Film Deposition for Applications in Spintronic Devices

Authors

Cynthia Nnokwe, Edward E. Whitacre Jr. College of Engineering
Connor J. Cunningham, University of Northern IowaFollow
Wenhao Liu, The University of Texas at Dallas
Gaihua Ye, Edward E. Whitacre Jr. College of EngineeringFollow
Tri Nguyen, Edward E. Whitacre Jr. College of Engineering
Kai Wu, Edward E. Whitacre Jr. College of Engineering
Colin Hemesath, University of Northern Iowa
Caden Sadler, University of Northern Iowa
Pavel Lukashev, University of Northern Iowa
Paul M. Shand, University of Northern Iowa
Andrew James Stollenwerk, University of Northern IowaFollow
Jia An Yan, Towson UniversityFollow

Document Type

Article

Keywords

CrI 3, first-principles calculation, Ni thin film, Raman spectroscopy, spin wave, van der Waals magnet

Journal/Book/Conference Title

ACS Applied Nano Materials

Volume

8

Issue

5

First Page

2412

Last Page

2420

Abstract

Chromium triiodide (CrI3), a van der Waals magnet, has recently been shown to host Ising ferromagnetism down to the monolayer limit. It is a potentially important material in 2D magnet-based applications, such as magnetic sensors and spintronic devices. Prior studies have revealed the coexistence of two different types of interlayer magnetic coupling, the antiferromagnetic (AFM) coupling near the surface and ferromagnetic (FM) coupling in the deep bulk layers, in pristine CrI3 crystals below the Curie temperature. In this study, we used Ni thin film deposition to tune the surface magnetic states in bulk CrI3. A nanometer thickness (4 nm thick) of Ni was deposited on the surface of CrI3 using electron-beam evaporation to form a Ni/CrI3 heterostructure. The deposited Ni thin layer forms nanoclusters that completely cover the CrI3 surface. Magnetic states of CrI3 before and after Ni deposition are probed by ultralow-frequency magneto-Raman spectroscopy. Instead of seeing three spin wave branches in Raman scattering below 2 T, as in pristine bulk CrI3, in Ni/CrI3, we observe only a single spin wave branch, which is softened compared to that in pristine CrI3 and displays a Zeeman shift under an out-of-plane magnetic field up to 7 T. This observation reveals that the AFM layers on pristine CrI3 crystal surfaces transit into FM layers, so the entire CrI3 crystal is in the FM state after Ni deposition. First-principles calculations show that Ni atoms tend to diffuse into the CrI3 lattice, and the FM interlayer coupling has a much lower energy than AFM coupling in the presence of Ni atoms. Our studies show that the magnetic state of CrI3 can be modified through deposition of a thin metal layer on the surface, offering a route for controlling the spin degree of freedom in van der Waals magnets.

Department

Department of Physics

Original Publication Date

1-29-2025

DOI of published version

10.1021/acsanm.4c06641

Recommended Citation

Nnokwe, Cynthia; Cunningham, Connor J.; Liu, Wenhao; Ye, Gaihua; Nguyen, Tri; Wu, Kai; Hemesath, Colin; Sadler, Caden; Lukashev, Pavel; Shand, Paul M.; Stollenwerk, Andrew James; and Yan, Jia An, "Tuning the Magnetic Properties of CrI3 Using Ni Thin Film Deposition for Applications in Spintronic Devices" (2025). Faculty Publications. 6755.
https://scholarworks.uni.edu/facpub/6755