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Main Authors: Meneses, Fernando, Qi, Rongrong, Healey, Alexander J., You, Yi, Robertson, Islay O., Scholten, Sam C., Keerthi, Ashok, Harrison, Gary, Hollenberg, Lloyd C. L., Radha, Boya, Tetienne, Jean-Philippe
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2307.10561
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author Meneses, Fernando
Qi, Rongrong
Healey, Alexander J.
You, Yi
Robertson, Islay O.
Scholten, Sam C.
Keerthi, Ashok
Harrison, Gary
Hollenberg, Lloyd C. L.
Radha, Boya
Tetienne, Jean-Philippe
author_facet Meneses, Fernando
Qi, Rongrong
Healey, Alexander J.
You, Yi
Robertson, Islay O.
Scholten, Sam C.
Keerthi, Ashok
Harrison, Gary
Hollenberg, Lloyd C. L.
Radha, Boya
Tetienne, Jean-Philippe
contents Magnetic van der Waals materials are often proposed for use in future spintronic devices, aiming to leverage the combination of long-range magnetic order and near-atomic thinness to produce energy-efficient components. One class of material that has been discussed in this context are the iron halides FeCl$_2$ and FeBr$_2$, which are A-type antiferromagnets with strong uniaxial magnetocrystalline anisotropy. However, despite characterization of the bulk materials, the possibility for sustaining the magnetic behaviors that would underpin such applications in thin flakes has not been investigated. In this work, we use nitrogen-vacancy (NV) center microscopy to quantitatively image magnetism in individual exfoliated flakes of these iron halides, revealing the absence of magnetic remanence, a weak induced magnetization under bias field and variable behavior versus temperature. We show that our results are consistent with the antiferromagnetic behavior of the bulk material with a soft ferromagnetic uncompensated layer, indicating that extended ($>1~μ$m) ferromagnetic domains are not sustained even at low temperatures (down to 4 K). Finally, we find that the magnetic order is strongly affected by the sample preparation, with a surprising diamagnetic order observed in a thin, hydrated sample.
format Preprint
id arxiv_https___arxiv_org_abs_2307_10561
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Stray magnetic field imaging of thin exfoliated iron halides flakes
Meneses, Fernando
Qi, Rongrong
Healey, Alexander J.
You, Yi
Robertson, Islay O.
Scholten, Sam C.
Keerthi, Ashok
Harrison, Gary
Hollenberg, Lloyd C. L.
Radha, Boya
Tetienne, Jean-Philippe
Materials Science
Magnetic van der Waals materials are often proposed for use in future spintronic devices, aiming to leverage the combination of long-range magnetic order and near-atomic thinness to produce energy-efficient components. One class of material that has been discussed in this context are the iron halides FeCl$_2$ and FeBr$_2$, which are A-type antiferromagnets with strong uniaxial magnetocrystalline anisotropy. However, despite characterization of the bulk materials, the possibility for sustaining the magnetic behaviors that would underpin such applications in thin flakes has not been investigated. In this work, we use nitrogen-vacancy (NV) center microscopy to quantitatively image magnetism in individual exfoliated flakes of these iron halides, revealing the absence of magnetic remanence, a weak induced magnetization under bias field and variable behavior versus temperature. We show that our results are consistent with the antiferromagnetic behavior of the bulk material with a soft ferromagnetic uncompensated layer, indicating that extended ($>1~μ$m) ferromagnetic domains are not sustained even at low temperatures (down to 4 K). Finally, we find that the magnetic order is strongly affected by the sample preparation, with a surprising diamagnetic order observed in a thin, hydrated sample.
title Stray magnetic field imaging of thin exfoliated iron halides flakes
topic Materials Science
url https://arxiv.org/abs/2307.10561