Visualizing Atomically Layered Magnetism in CrSBr

Daniel J. Rizzo; Alexander S. McLeod; Caitlin Carnahan; Evan J. Telford; Avalon H. Dismukes; Ren A. Wiscons; Yinan Dong; Colin Nuckolls; Cory R. Dean; Abhay N. Pasupathy; Xavier Roy; Di Xiao; D. N. Basov

doi:10.1002/adma.202201000

Visualizing Atomically Layered Magnetism in CrSBr

Daniel J. Rizzo, Alexander S. McLeod, Caitlin Carnahan, Evan J. Telford, Avalon H. Dismukes, Ren A. Wiscons, Yinan Dong, Colin Nuckolls, Cory R. Dean, Abhay N. Pasupathy, Xavier Roy, Di Xiao, D. N. Basov

Physics and Astronomy (Twin Cities)

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

2D materials can host long-range magnetic order in the presence of underlying magnetic anisotropy. The ability to realize the full potential of 2D magnets necessitates systematic investigation of the role of individual atomic layers and nanoscale inhomogeneity (i.e., strain) on the emergence of stable magnetic phases. Here, spatially dependent magnetism in few-layer CrSBr is revealed using magnetic force microscopy (MFM) and Monte Carlo-based simulations. Nanoscale visualization of the magnetic sheet susceptibility is extracted from MFM data and force–distance curves, revealing a characteristic onset of both intra- and interlayer magnetic correlations as a function of temperature and layer-thickness. These results demonstrate that the presence of a single uncompensated layer in odd-layer terraces significantly reduces the stability of the low-temperature antiferromagnetic (AFM) phase and gives rise to multiple coexisting magnetic ground states at temperatures close to the bulk Néel temperature (T_N). Furthermore, the AFM phase can be reliably suppressed using modest fields (≈16 mT) from the MFM probe, behaving as a nanoscale magnetic switch. This prototypical study of few-layer CrSBr demonstrates the critical role of layer parity on field-tunable 2D magnetism and validates MFM for use in nanomagnetometry of 2D materials (despite the ubiquitous absence of bulk zero-field magnetism in magnetized sheets).

Original language	English (US)
Article number	2201000
Journal	Advanced Materials
Volume	34
Issue number	27
DOIs	https://doi.org/10.1002/adma.202201000
State	Published - Jul 7 2022

Bibliographical note

Funding Information:
Research at Columbia University and University of Washington was supported as part of the Energy Frontier Research Center on Programmable Quantum Materials funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), under Award No. DE‐SC0019443. R.A.W. was supported by an Arnold O. Beckman Fellowship in Chemical Sciences. A.H.D. was supported by the National Science Foundation graduate research fellowship programme (DGE 16‐44869).

Publisher Copyright:
© 2022 Wiley-VCH GmbH.

Keywords

2D magnets
2D materials
magnetic force microscopy
magnetometry
van der Waals materials

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title = "Visualizing Atomically Layered Magnetism in CrSBr",

abstract = "2D materials can host long-range magnetic order in the presence of underlying magnetic anisotropy. The ability to realize the full potential of 2D magnets necessitates systematic investigation of the role of individual atomic layers and nanoscale inhomogeneity (i.e., strain) on the emergence of stable magnetic phases. Here, spatially dependent magnetism in few-layer CrSBr is revealed using magnetic force microscopy (MFM) and Monte Carlo-based simulations. Nanoscale visualization of the magnetic sheet susceptibility is extracted from MFM data and force–distance curves, revealing a characteristic onset of both intra- and interlayer magnetic correlations as a function of temperature and layer-thickness. These results demonstrate that the presence of a single uncompensated layer in odd-layer terraces significantly reduces the stability of the low-temperature antiferromagnetic (AFM) phase and gives rise to multiple coexisting magnetic ground states at temperatures close to the bulk N{\'e}el temperature (TN). Furthermore, the AFM phase can be reliably suppressed using modest fields (≈16 mT) from the MFM probe, behaving as a nanoscale magnetic switch. This prototypical study of few-layer CrSBr demonstrates the critical role of layer parity on field-tunable 2D magnetism and validates MFM for use in nanomagnetometry of 2D materials (despite the ubiquitous absence of bulk zero-field magnetism in magnetized sheets).",

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author = "Rizzo, {Daniel J.} and McLeod, {Alexander S.} and Caitlin Carnahan and Telford, {Evan J.} and Dismukes, {Avalon H.} and Wiscons, {Ren A.} and Yinan Dong and Colin Nuckolls and Dean, {Cory R.} and Pasupathy, {Abhay N.} and Xavier Roy and Di Xiao and Basov, {D. N.}",

note = "Funding Information: Research at Columbia University and University of Washington was supported as part of the Energy Frontier Research Center on Programmable Quantum Materials funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), under Award No. DE‐SC0019443. R.A.W. was supported by an Arnold O. Beckman Fellowship in Chemical Sciences. A.H.D. was supported by the National Science Foundation graduate research fellowship programme (DGE 16‐44869). Publisher Copyright: {\textcopyright} 2022 Wiley-VCH GmbH.",

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AU - Pasupathy, Abhay N.

AU - Roy, Xavier

AU - Xiao, Di

AU - Basov, D. N.

N1 - Funding Information: Research at Columbia University and University of Washington was supported as part of the Energy Frontier Research Center on Programmable Quantum Materials funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), under Award No. DE‐SC0019443. R.A.W. was supported by an Arnold O. Beckman Fellowship in Chemical Sciences. A.H.D. was supported by the National Science Foundation graduate research fellowship programme (DGE 16‐44869). Publisher Copyright: © 2022 Wiley-VCH GmbH.

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N2 - 2D materials can host long-range magnetic order in the presence of underlying magnetic anisotropy. The ability to realize the full potential of 2D magnets necessitates systematic investigation of the role of individual atomic layers and nanoscale inhomogeneity (i.e., strain) on the emergence of stable magnetic phases. Here, spatially dependent magnetism in few-layer CrSBr is revealed using magnetic force microscopy (MFM) and Monte Carlo-based simulations. Nanoscale visualization of the magnetic sheet susceptibility is extracted from MFM data and force–distance curves, revealing a characteristic onset of both intra- and interlayer magnetic correlations as a function of temperature and layer-thickness. These results demonstrate that the presence of a single uncompensated layer in odd-layer terraces significantly reduces the stability of the low-temperature antiferromagnetic (AFM) phase and gives rise to multiple coexisting magnetic ground states at temperatures close to the bulk Néel temperature (TN). Furthermore, the AFM phase can be reliably suppressed using modest fields (≈16 mT) from the MFM probe, behaving as a nanoscale magnetic switch. This prototypical study of few-layer CrSBr demonstrates the critical role of layer parity on field-tunable 2D magnetism and validates MFM for use in nanomagnetometry of 2D materials (despite the ubiquitous absence of bulk zero-field magnetism in magnetized sheets).

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Visualizing Atomically Layered Magnetism in CrSBr

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