Magnetization reversal of ferromagnetic nanosprings affected by helical shape

Da Yeon Nam; Aleksei Yu Samardak; Yoo Sang Jeon; Su Hyo Kim; Alexander V. Davydenko; Alexey V. Ognev; Alexander S. Samardak; Young Keun Kim

doi:10.1039/c8nr05655b

Magnetization reversal of ferromagnetic nanosprings affected by helical shape

Da Yeon Nam
, Aleksei Yu Samardak
, Yoo Sang Jeon
, Su Hyo Kim
, Alexander V. Davydenko
, Alexey V. Ognev
, Alexander S. Samardak^*
, Young Keun Kim

^*Corresponding author for this work

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

20 Citations (Scopus)

Abstract

Helicity, a natural property of macro-, micro-, and nano-objects, potentially offers a new dimension to mechanical and electromagnetic applications for creating emerging nanodevices, such as nanorobots, nanomagnets, nanosensors, and high-density magnetic memory. Helical magnetic nanosprings are unique objects with remarkable magnetic properties, including the absence of stray fields in remanence owing to the chiral geometry, which makes them promising for data storage devices, nanoelectromechanical systems, and biomedical usage. Here, we investigated Co and CoFe nanospring arrays electrodeposited in highly ordered nanoporous templates. We report helical-shape-driven magnetization reversal of the nanosprings in comparison with the behavior of dipolarly coupled nanowires. We reveal two magnetization reversal modes depending on the orientation of the external magnetic field: coherent rotation of magnetization in the longitudinal geometry and three-dimensional vortex domain wall motion in the transverse geometry. The experimental findings are supported by analytical calculations and micromagnetic simulations that help to explain the field-dependent spin configurations observed by magnetic force microscopy.

Original language	English
Pages (from-to)	20405-20413
Number of pages	9
Journal	Nanoscale
Volume	10
Issue number	43
DOIs	https://doi.org/10.1039/c8nr05655b
Publication status	Published - 2018 Nov 21

Bibliographical note

Funding Information:
This work was supported by Samsung Research Funding & Incubation Center of Samsung Electronics under Project Number SRFC-TA1703-06, by the Russian Foundation for Basic Research (grant 16-02-01015), by the Russian Ministry of Education and Science (under state tasks 3.5178.2017/8.9 and 3.4956.2017), and by Act 211 of the Government of the Russian Federation (contract no. 02.A03.21.0011). The magnetic measurements were carried out on the equipment of the Key Laboratory “Materials” of Far Eastern Federal University.

Publisher Copyright:
© 2018 The Royal Society of Chemistry.

ASJC Scopus subject areas

General Materials Science

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10.1039/c8nr05655b

Cite this

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title = "Magnetization reversal of ferromagnetic nanosprings affected by helical shape",

abstract = "Helicity, a natural property of macro-, micro-, and nano-objects, potentially offers a new dimension to mechanical and electromagnetic applications for creating emerging nanodevices, such as nanorobots, nanomagnets, nanosensors, and high-density magnetic memory. Helical magnetic nanosprings are unique objects with remarkable magnetic properties, including the absence of stray fields in remanence owing to the chiral geometry, which makes them promising for data storage devices, nanoelectromechanical systems, and biomedical usage. Here, we investigated Co and CoFe nanospring arrays electrodeposited in highly ordered nanoporous templates. We report helical-shape-driven magnetization reversal of the nanosprings in comparison with the behavior of dipolarly coupled nanowires. We reveal two magnetization reversal modes depending on the orientation of the external magnetic field: coherent rotation of magnetization in the longitudinal geometry and three-dimensional vortex domain wall motion in the transverse geometry. The experimental findings are supported by analytical calculations and micromagnetic simulations that help to explain the field-dependent spin configurations observed by magnetic force microscopy.",

author = "Nam, \{Da Yeon\} and Samardak, \{Aleksei Yu\} and Jeon, \{Yoo Sang\} and Kim, \{Su Hyo\} and Davydenko, \{Alexander V.\} and Ognev, \{Alexey V.\} and Samardak, \{Alexander S.\} and Kim, \{Young Keun\}",

note = "Funding Information: This work was supported by Samsung Research Funding \& Incubation Center of Samsung Electronics under Project Number SRFC-TA1703-06, by the Russian Foundation for Basic Research (grant 16-02-01015), by the Russian Ministry of Education and Science (under state tasks 3.5178.2017/8.9 and 3.4956.2017), and by Act 211 of the Government of the Russian Federation (contract no. 02.A03.21.0011). The magnetic measurements were carried out on the equipment of the Key Laboratory “Materials” of Far Eastern Federal University. Publisher Copyright: {\textcopyright} 2018 The Royal Society of Chemistry.",

year = "2018",

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doi = "10.1039/c8nr05655b",

language = "English",

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AU - Nam, Da Yeon

AU - Samardak, Aleksei Yu

AU - Jeon, Yoo Sang

AU - Kim, Su Hyo

AU - Davydenko, Alexander V.

AU - Ognev, Alexey V.

AU - Samardak, Alexander S.

AU - Kim, Young Keun

N1 - Funding Information: This work was supported by Samsung Research Funding & Incubation Center of Samsung Electronics under Project Number SRFC-TA1703-06, by the Russian Foundation for Basic Research (grant 16-02-01015), by the Russian Ministry of Education and Science (under state tasks 3.5178.2017/8.9 and 3.4956.2017), and by Act 211 of the Government of the Russian Federation (contract no. 02.A03.21.0011). The magnetic measurements were carried out on the equipment of the Key Laboratory “Materials” of Far Eastern Federal University. Publisher Copyright: © 2018 The Royal Society of Chemistry.

PY - 2018/11/21

Y1 - 2018/11/21

N2 - Helicity, a natural property of macro-, micro-, and nano-objects, potentially offers a new dimension to mechanical and electromagnetic applications for creating emerging nanodevices, such as nanorobots, nanomagnets, nanosensors, and high-density magnetic memory. Helical magnetic nanosprings are unique objects with remarkable magnetic properties, including the absence of stray fields in remanence owing to the chiral geometry, which makes them promising for data storage devices, nanoelectromechanical systems, and biomedical usage. Here, we investigated Co and CoFe nanospring arrays electrodeposited in highly ordered nanoporous templates. We report helical-shape-driven magnetization reversal of the nanosprings in comparison with the behavior of dipolarly coupled nanowires. We reveal two magnetization reversal modes depending on the orientation of the external magnetic field: coherent rotation of magnetization in the longitudinal geometry and three-dimensional vortex domain wall motion in the transverse geometry. The experimental findings are supported by analytical calculations and micromagnetic simulations that help to explain the field-dependent spin configurations observed by magnetic force microscopy.

AB - Helicity, a natural property of macro-, micro-, and nano-objects, potentially offers a new dimension to mechanical and electromagnetic applications for creating emerging nanodevices, such as nanorobots, nanomagnets, nanosensors, and high-density magnetic memory. Helical magnetic nanosprings are unique objects with remarkable magnetic properties, including the absence of stray fields in remanence owing to the chiral geometry, which makes them promising for data storage devices, nanoelectromechanical systems, and biomedical usage. Here, we investigated Co and CoFe nanospring arrays electrodeposited in highly ordered nanoporous templates. We report helical-shape-driven magnetization reversal of the nanosprings in comparison with the behavior of dipolarly coupled nanowires. We reveal two magnetization reversal modes depending on the orientation of the external magnetic field: coherent rotation of magnetization in the longitudinal geometry and three-dimensional vortex domain wall motion in the transverse geometry. The experimental findings are supported by analytical calculations and micromagnetic simulations that help to explain the field-dependent spin configurations observed by magnetic force microscopy.

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EP - 20413

JO - Nanoscale

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ER -

Magnetization reversal of ferromagnetic nanosprings affected by helical shape

Abstract

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