Phase evolution of magnetite nanocrystals on oxide supports via template-free bismuth ferrite precursor approach

Jeffrey Cheung; Kashinath Bogle; Xuan Cheng; Jivika Sullaphen; Chang Yang Kuo; Ying Jiun Chen; Hong Ji Lin; Chien Te Chen; Jan Chi Yang; Ying Hao Chu; Nagarajan Valanoor

doi:10.1063/1.4766748

Phase evolution of magnetite nanocrystals on oxide supports via template-free bismuth ferrite precursor approach

Jeffrey Cheung, Kashinath Bogle, Xuan Cheng, Jivika Sullaphen, Chang Yang Kuo, Ying Jiun Chen, Hong Ji Lin, Chien Te Chen, Jan Chi Yang, Ying Hao Chu, Nagarajan Valanoor

物理學系

研究成果: Article › 同行評審

8 引文斯高帕斯（Scopus）

摘要

This report investigates the phase evolution pathway of magnetite nanocrystal synthesis on oxide-supported substrates. A template-free phase separation approach, which exploits the thermodynamic instability of ternary perovskite BiFeO₃ and inherent volatility of bismuth oxide in low oxygen pressure and high temperature is presented. The formation of an intermediate hematite nanocrystal phase is found as a key step that controls the eventual size and morphology of the magnetite nanocrystals. X-ray absorption spectra measurements and X-ray magnetic circular dichroism confirm that the spectral fingerprints of the magnetite nanocrystals match with that of bulk crystals. Magnetic measurements show that magnetic anisotropy is directly attributed to the nanocrystal morphology.

原文	English
文章編號	104321
期刊	Journal of Applied Physics
卷	112
發行號	10
DOIs	https://doi.org/10.1063/1.4766748
出版狀態	Published - 2012 11月 15

All Science Journal Classification (ASJC) codes

一般物理與天文學

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10.1063/1.4766748

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title = "Phase evolution of magnetite nanocrystals on oxide supports via template-free bismuth ferrite precursor approach",

abstract = "This report investigates the phase evolution pathway of magnetite nanocrystal synthesis on oxide-supported substrates. A template-free phase separation approach, which exploits the thermodynamic instability of ternary perovskite BiFeO3 and inherent volatility of bismuth oxide in low oxygen pressure and high temperature is presented. The formation of an intermediate hematite nanocrystal phase is found as a key step that controls the eventual size and morphology of the magnetite nanocrystals. X-ray absorption spectra measurements and X-ray magnetic circular dichroism confirm that the spectral fingerprints of the magnetite nanocrystals match with that of bulk crystals. Magnetic measurements show that magnetic anisotropy is directly attributed to the nanocrystal morphology.",

author = "Jeffrey Cheung and Kashinath Bogle and Xuan Cheng and Jivika Sullaphen and Kuo, {Chang Yang} and Chen, {Ying Jiun} and Lin, {Hong Ji} and Chen, {Chien Te} and Yang, {Jan Chi} and Chu, {Ying Hao} and Nagarajan Valanoor",

note = "Funding Information: The work at UNSW was supported by an ARC Discovery Project. Y.H.C. would like to acknowledge the support of the National Science Council, R.O.C., under Contract No. NSC-100-2119-M-009-003. ",

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AU - Cheung, Jeffrey

AU - Bogle, Kashinath

AU - Cheng, Xuan

AU - Sullaphen, Jivika

AU - Kuo, Chang Yang

AU - Chen, Ying Jiun

AU - Lin, Hong Ji

AU - Chen, Chien Te

AU - Yang, Jan Chi

AU - Chu, Ying Hao

AU - Valanoor, Nagarajan

N1 - Funding Information: The work at UNSW was supported by an ARC Discovery Project. Y.H.C. would like to acknowledge the support of the National Science Council, R.O.C., under Contract No. NSC-100-2119-M-009-003.

PY - 2012/11/15

Y1 - 2012/11/15

N2 - This report investigates the phase evolution pathway of magnetite nanocrystal synthesis on oxide-supported substrates. A template-free phase separation approach, which exploits the thermodynamic instability of ternary perovskite BiFeO3 and inherent volatility of bismuth oxide in low oxygen pressure and high temperature is presented. The formation of an intermediate hematite nanocrystal phase is found as a key step that controls the eventual size and morphology of the magnetite nanocrystals. X-ray absorption spectra measurements and X-ray magnetic circular dichroism confirm that the spectral fingerprints of the magnetite nanocrystals match with that of bulk crystals. Magnetic measurements show that magnetic anisotropy is directly attributed to the nanocrystal morphology.

AB - This report investigates the phase evolution pathway of magnetite nanocrystal synthesis on oxide-supported substrates. A template-free phase separation approach, which exploits the thermodynamic instability of ternary perovskite BiFeO3 and inherent volatility of bismuth oxide in low oxygen pressure and high temperature is presented. The formation of an intermediate hematite nanocrystal phase is found as a key step that controls the eventual size and morphology of the magnetite nanocrystals. X-ray absorption spectra measurements and X-ray magnetic circular dichroism confirm that the spectral fingerprints of the magnetite nanocrystals match with that of bulk crystals. Magnetic measurements show that magnetic anisotropy is directly attributed to the nanocrystal morphology.

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Phase evolution of magnetite nanocrystals on oxide supports via template-free bismuth ferrite precursor approach

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