Giant magnetic coercivity in Fe3C-filled carbon nanotubes

Dan Liu; Jie Zhu; Sameera Ivaturi; Yi He; Shanling Wang; Jiayu Wang; Sijie Zhang; Maureen A.C. Willis; Filippo S. Boi

doi:10.1039/c7ra13671d

Giant magnetic coercivity in Fe₃C-filled carbon nanotubes

Dan Liu, Jie Zhu, Sameera Ivaturi, Yi He, Shanling Wang, Jiayu Wang, Sijie Zhang, Maureen A.C. Willis^*, Filippo S. Boi

^*Corresponding author for this work

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

8 Citations (Scopus)

Abstract

One of the major challenges in the synthesis of ferromagnetically filled carbon nanotubes is the achievement of high coercivities. Up to now the highest coercivity has been shown to be 2200 Oe at 2 K ranging down to 500 Oe at temperatures of 300 K. Here we show that the anomalously large coercivity of 3440 Oe is observed in comparable samples. By comparing our result to those reported in previous studies no correlation is found between coercivity and the shape anisotropy or the crystal-diameter. Instead we suggest that the main parameter which controls the coercivity of these structures is the interplay of the grain size and shape anisotropy. We attribute the anomalous coercivity to the grain size being below the calculated single magnetic domain limit.

Original language	English
Pages (from-to)	13820-13825
Number of pages	6
Journal	RSC Advances
Volume	8
Issue number	25
DOIs	https://doi.org/10.1039/c7ra13671d
Publication status	Published - 2018
Externally published	Yes

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abstract = "One of the major challenges in the synthesis of ferromagnetically filled carbon nanotubes is the achievement of high coercivities. Up to now the highest coercivity has been shown to be 2200 Oe at 2 K ranging down to 500 Oe at temperatures of 300 K. Here we show that the anomalously large coercivity of 3440 Oe is observed in comparable samples. By comparing our result to those reported in previous studies no correlation is found between coercivity and the shape anisotropy or the crystal-diameter. Instead we suggest that the main parameter which controls the coercivity of these structures is the interplay of the grain size and shape anisotropy. We attribute the anomalous coercivity to the grain size being below the calculated single magnetic domain limit.",

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AU - Liu, Dan

AU - Zhu, Jie

AU - Ivaturi, Sameera

AU - He, Yi

AU - Wang, Shanling

AU - Wang, Jiayu

AU - Zhang, Sijie

AU - Willis, Maureen A.C.

AU - Boi, Filippo S.

PY - 2018

Y1 - 2018

N2 - One of the major challenges in the synthesis of ferromagnetically filled carbon nanotubes is the achievement of high coercivities. Up to now the highest coercivity has been shown to be 2200 Oe at 2 K ranging down to 500 Oe at temperatures of 300 K. Here we show that the anomalously large coercivity of 3440 Oe is observed in comparable samples. By comparing our result to those reported in previous studies no correlation is found between coercivity and the shape anisotropy or the crystal-diameter. Instead we suggest that the main parameter which controls the coercivity of these structures is the interplay of the grain size and shape anisotropy. We attribute the anomalous coercivity to the grain size being below the calculated single magnetic domain limit.

AB - One of the major challenges in the synthesis of ferromagnetically filled carbon nanotubes is the achievement of high coercivities. Up to now the highest coercivity has been shown to be 2200 Oe at 2 K ranging down to 500 Oe at temperatures of 300 K. Here we show that the anomalously large coercivity of 3440 Oe is observed in comparable samples. By comparing our result to those reported in previous studies no correlation is found between coercivity and the shape anisotropy or the crystal-diameter. Instead we suggest that the main parameter which controls the coercivity of these structures is the interplay of the grain size and shape anisotropy. We attribute the anomalous coercivity to the grain size being below the calculated single magnetic domain limit.

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DO - 10.1039/c7ra13671d

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VL - 8

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EP - 13825

JO - RSC Advances

JF - RSC Advances

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Giant magnetic coercivity in Fe₃C-filled carbon nanotubes

Abstract

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