Vertically aligned single-crystalline CoFe2O4 nanobrush architectures with high magnetization and tailored magnetic anisotropy

Lisha Fan; Xiang Gao; Thomas O. Farmer; Dongkyu Lee; Er Jia Guo; Sai Mu; Kai Wang; Michael R. Fitzsimmons; Matthew F. Chisholm; Thomas Z. Ward; Gyula Eres; Ho Nyung Lee

doi:10.3390/nano10030472

Vertically aligned single-crystalline CoFe₂O₄ nanobrush architectures with high magnetization and tailored magnetic anisotropy

Lisha Fan, Xiang Gao, Thomas O. Farmer, Dongkyu Lee, Er Jia Guo, Sai Mu, Kai Wang, Michael R. Fitzsimmons, Matthew F. Chisholm, Thomas Z. Ward, Gyula Eres, Ho Nyung Lee

Quantum Heterostructures

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

8 Scopus citations

Abstract

Micrometer-tall vertically aligned single-crystalline CoFe2O4 nanobrush architectures with extraordinarily large aspect ratio have been achieved by the precise control of a kinetic and thermodynamic non-equilibrium pulsed laser epitaxy process. Direct observations by scanning transmission electron microscopy reveal that the nanobrush crystal is mostly defect-free by nature, and epitaxially connected to the substrate through a continuous 2D interface layer. In contrast, periodic dislocations and lattice defects such as anti-phase boundaries and twin boundaries are frequently observed in the 2D interface layer, suggesting that interface misfit strain relaxation under a non-equilibrium growth condition plays a critical role in the self-assembly of such artificial architectures. Magnetic property measurements have found that the nanobrushes exhibit a saturation magnetization value of 6.16 μB/f.u., which is much higher than the bulk value. The discovery not only enables insights into an effective route for fabricating unconventional high-quality nanostructures, but also demonstrates a novel magnetic architecture with potential applications in nanomagnetic devices.

Original language	English
Article number	472
Journal	Nanomaterials
Volume	10
Issue number	3
DOIs	https://doi.org/10.3390/nano10030472
State	Published - Mar 2020

Funding

Acknowledgments: This work was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences, Materials Science and Engineering Division. The STEM and SEM work used resources at the Center for Nanophase Materials Sciences, which is a U.S. DOE Office of Science User Facility operated by Oak Ridge National Laboratory. L. F. conducted this research while at ORNL and was in part supported by Zhejiang University of Technology for her efforts to write and revise the manuscript. This work was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Science and Engineering Division. Funding: This work was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Science and Engineering Division.

Keywords

Cobalt ferrite
Magnetization
Nanobrush
Pulsed laser epitaxy
Single crystalline
Tailored anisotropy
Vertically aligned

Access to Document

10.3390/nano10030472

Cite this

@article{65dc9b54ceed4539a3b3efcceccad138,

title = "Vertically aligned single-crystalline CoFe2O4 nanobrush architectures with high magnetization and tailored magnetic anisotropy",

abstract = "Micrometer-tall vertically aligned single-crystalline CoFe2O4 nanobrush architectures with extraordinarily large aspect ratio have been achieved by the precise control of a kinetic and thermodynamic non-equilibrium pulsed laser epitaxy process. Direct observations by scanning transmission electron microscopy reveal that the nanobrush crystal is mostly defect-free by nature, and epitaxially connected to the substrate through a continuous 2D interface layer. In contrast, periodic dislocations and lattice defects such as anti-phase boundaries and twin boundaries are frequently observed in the 2D interface layer, suggesting that interface misfit strain relaxation under a non-equilibrium growth condition plays a critical role in the self-assembly of such artificial architectures. Magnetic property measurements have found that the nanobrushes exhibit a saturation magnetization value of 6.16 μB/f.u., which is much higher than the bulk value. The discovery not only enables insights into an effective route for fabricating unconventional high-quality nanostructures, but also demonstrates a novel magnetic architecture with potential applications in nanomagnetic devices.",

keywords = "Cobalt ferrite, Magnetization, Nanobrush, Pulsed laser epitaxy, Single crystalline, Tailored anisotropy, Vertically aligned",

author = "Lisha Fan and Xiang Gao and Farmer, \{Thomas O.\} and Dongkyu Lee and Guo, \{Er Jia\} and Sai Mu and Kai Wang and Fitzsimmons, \{Michael R.\} and Chisholm, \{Matthew F.\} and Ward, \{Thomas Z.\} and Gyula Eres and Lee, \{Ho Nyung\}",

note = "Publisher Copyright: {\textcopyright} 2020 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2020",

month = mar,

doi = "10.3390/nano10030472",

language = "English",

volume = "10",

journal = "Nanomaterials",

issn = "2079-4991",

publisher = "MDPI",

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T1 - Vertically aligned single-crystalline CoFe2O4 nanobrush architectures with high magnetization and tailored magnetic anisotropy

AU - Fan, Lisha

AU - Gao, Xiang

AU - Farmer, Thomas O.

AU - Lee, Dongkyu

AU - Guo, Er Jia

AU - Mu, Sai

AU - Wang, Kai

AU - Fitzsimmons, Michael R.

AU - Chisholm, Matthew F.

AU - Ward, Thomas Z.

AU - Eres, Gyula

AU - Lee, Ho Nyung

PY - 2020/3

Y1 - 2020/3

N2 - Micrometer-tall vertically aligned single-crystalline CoFe2O4 nanobrush architectures with extraordinarily large aspect ratio have been achieved by the precise control of a kinetic and thermodynamic non-equilibrium pulsed laser epitaxy process. Direct observations by scanning transmission electron microscopy reveal that the nanobrush crystal is mostly defect-free by nature, and epitaxially connected to the substrate through a continuous 2D interface layer. In contrast, periodic dislocations and lattice defects such as anti-phase boundaries and twin boundaries are frequently observed in the 2D interface layer, suggesting that interface misfit strain relaxation under a non-equilibrium growth condition plays a critical role in the self-assembly of such artificial architectures. Magnetic property measurements have found that the nanobrushes exhibit a saturation magnetization value of 6.16 μB/f.u., which is much higher than the bulk value. The discovery not only enables insights into an effective route for fabricating unconventional high-quality nanostructures, but also demonstrates a novel magnetic architecture with potential applications in nanomagnetic devices.

AB - Micrometer-tall vertically aligned single-crystalline CoFe2O4 nanobrush architectures with extraordinarily large aspect ratio have been achieved by the precise control of a kinetic and thermodynamic non-equilibrium pulsed laser epitaxy process. Direct observations by scanning transmission electron microscopy reveal that the nanobrush crystal is mostly defect-free by nature, and epitaxially connected to the substrate through a continuous 2D interface layer. In contrast, periodic dislocations and lattice defects such as anti-phase boundaries and twin boundaries are frequently observed in the 2D interface layer, suggesting that interface misfit strain relaxation under a non-equilibrium growth condition plays a critical role in the self-assembly of such artificial architectures. Magnetic property measurements have found that the nanobrushes exhibit a saturation magnetization value of 6.16 μB/f.u., which is much higher than the bulk value. The discovery not only enables insights into an effective route for fabricating unconventional high-quality nanostructures, but also demonstrates a novel magnetic architecture with potential applications in nanomagnetic devices.

KW - Cobalt ferrite

KW - Magnetization

KW - Nanobrush

KW - Pulsed laser epitaxy

KW - Single crystalline

KW - Tailored anisotropy

KW - Vertically aligned

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