Revealing room temperature ferromagnetism in exfoliated Fe5GeTe2flakes with quantum magnetic imaging

Hang Chen, Shahidul Asif, Matthew Whalen, Jeyson Támara-Isaza, Brennan Luetke, Yang Wang, Xinhao Wang, Millicent Ayako, Saurabh Lamsal, Andrew F. May, Michael A. McGuire, Chitraleema Chakraborty, John Q. Xiao, Mark J.H. Ku

Research output: Contribution to journalArticlepeer-review

20 Scopus citations

Abstract

Van der Waals (vdW) material Fe5GeTe2, with its long-range ferromagnetic ordering near room temperature, has significant potential to become an enabling platform for implementing novel spintronic and quantum devices. To pave the way for applications, it is crucial to determine the magnetic properties when the thickness of Fe5GeTe2 reaches the few-layers regime. However, this is highly challenging due to the need for a characterization technique that is local, highly sensitive, artifact-free, and operational with minimal fabrication. Prior studies have indicated that Curie temperature T C can reach up to close to room temperature for exfoliated Fe5GeTe2 flakes, as measured via electrical transport; there is a need to validate these results with a measurement that reveals magnetism more directly. In this work, we investigate the magnetic properties of exfoliated thin flakes of vdW magnet Fe5GeTe2 via quantum magnetic imaging technique based on nitrogen vacancy centers in diamond. Through imaging the stray fields, we confirm room-temperature magnetic order in Fe5GeTe2 thin flakes with thickness down to 7 units cell. The stray field patterns and their response to magnetizing fields with different polarities is consistent with previously reported perpendicular easy-axis anisotropy. Furthermore, we perform imaging at different temperatures and determine the Curie temperature of the flakes at ≈300 K. These results provide the basis for realizing a room-temperature monolayer ferromagnet with Fe5GeTe2. This work also demonstrates that the imaging technique enables rapid screening of multiple flakes simultaneously as well as time-resolved imaging for monitoring time-dependent magnetic behaviors, thereby paving the way towards high throughput characterization of potential two-dimensional (2D) magnets near room temperature and providing critical insights into the evolution of domain behaviors in 2D magnets due to degradation.

Original languageEnglish
Article number025017
Journal2D Materials
Volume9
Issue number2
DOIs
StatePublished - Apr 2022

Funding

This research was partially supported by NSF through the University of Delaware Materials Research Science and Engineering Center DMR-2011824 Seed Award program. MW and JQX are supported by NSF through the University of Delaware Materials Research Science and Engineering Center DMR-2011824; additional support was received from NSF DMR grant #1904076 and NSF DMR grant #312181. CC acknowledges support from the University of Delaware Research Foundation. Crystal growth and characterization (AFM, MAM) were supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division.

FundersFunder number
NSF DMR1904076, 312181
University of Delaware Materials Research Science and Engineering CenterDMR-2011824
National Science Foundation
U.S. Department of Energy
University of Delaware Research Foundation
Office of Science
Basic Energy Sciences
Division of Materials Sciences and Engineering

    Keywords

    • 2D magnet
    • FeGeTe
    • quantum sensing

    Fingerprint

    Dive into the research topics of 'Revealing room temperature ferromagnetism in exfoliated Fe5GeTe2flakes with quantum magnetic imaging'. Together they form a unique fingerprint.

    Cite this