Standard

Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms. / Kuznetsov, Andrey A.; Novak, Ekaterina V.; Pyanzina, Elena S. и др.
в: Soft Matter, Том 19, № 24, 2023, стр. 4549-4561.

Результаты исследований: Вклад в журналСтатьяРецензирование

Harvard

Kuznetsov, AA, Novak, EV, Pyanzina, ES & Kantorovich, SS 2023, 'Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms', Soft Matter, Том. 19, № 24, стр. 4549-4561. https://doi.org/10.1039/D3SM00440F

APA

Kuznetsov, A. A., Novak, E. V., Pyanzina, E. S., & Kantorovich, S. S. (2023). Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms. Soft Matter, 19(24), 4549-4561. https://doi.org/10.1039/D3SM00440F

Vancouver

Kuznetsov AA, Novak EV, Pyanzina ES, Kantorovich SS. Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms. Soft Matter. 2023;19(24):4549-4561. doi: 10.1039/D3SM00440F

Author

Kuznetsov, Andrey A. ; Novak, Ekaterina V. ; Pyanzina, Elena S. и др. / Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms. в: Soft Matter. 2023 ; Том 19, № 24. стр. 4549-4561.

BibTeX

@article{b04169b99d7840b9b329e1896ef176ea,
title = "Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms",
abstract = "The necessity to improve magnetic building blocks in magnetic nano-structured soft materials stems from a fascinating potential these materials have in bio-medical applications and nanofluidics. Along with practical reasons, the interplay of magnetic and steric interactions on one hand, and entropy, on the other, makes magnetic soft matter fundamentally challenging. Recently, in order to tailor magnetic response of the magnetic particle suspensions, the idea arose to replace standard single-core nanoparticles with nano-sized clusters of single-domain nanoparticles (grains) rigidly bound together by solid polymer matrix - multicore magnetic nanoparticles (MMNPs). To pursue this idea, a profound understanding of the MMNP interactions and self-assembly is required. In this work we present a computational study of the MMNP suspensions and elucidate their self-assembly and magnetic susceptibility. We show that depending on the magnetic moment of individual grains the suspensions exhibit qualitatively distinct regimes. Firstly, if the grains are moderately interacting, they contribute to a significant decrease of the remanent magnetisation of MMNPs and as such to a decrease of the magnetic susceptibility, this way confirming previous findings. If the grains are strongly interacting, instead, they serve as anchor points and support formation of grain clusters that span through several MMNPs, leading to MMNP cluster formation and a drastic increase of the initial magnetic response. Both the topology of the clusters and their size distribution in MMNP suspensions is found to be notably different from those formed in conventional magnetic fluids or magnetorheological suspensions.",
author = "Kuznetsov, {Andrey A.} and Novak, {Ekaterina V.} and Pyanzina, {Elena S.} and Kantorovich, {Sofia S.}",
note = "This research has been supported by the Russian Science Foundation Grant No. 19-72-10033. S. S. K. was partially supported by Project SAM P 33748. Computer simulations were performed at the Ural Federal University cluster.",
year = "2023",
doi = "10.1039/D3SM00440F",
language = "English",
volume = "19",
pages = "4549--4561",
journal = "Soft Matter",
issn = "1744-683X",
publisher = "Royal Society of Chemistry",
number = "24",

}

RIS

TY - JOUR

T1 - Multicore-based ferrofluids in zero field: initial magnetic susceptibility and self-assembly mechanisms

AU - Kuznetsov, Andrey A.

AU - Novak, Ekaterina V.

AU - Pyanzina, Elena S.

AU - Kantorovich, Sofia S.

N1 - This research has been supported by the Russian Science Foundation Grant No. 19-72-10033. S. S. K. was partially supported by Project SAM P 33748. Computer simulations were performed at the Ural Federal University cluster.

PY - 2023

Y1 - 2023

N2 - The necessity to improve magnetic building blocks in magnetic nano-structured soft materials stems from a fascinating potential these materials have in bio-medical applications and nanofluidics. Along with practical reasons, the interplay of magnetic and steric interactions on one hand, and entropy, on the other, makes magnetic soft matter fundamentally challenging. Recently, in order to tailor magnetic response of the magnetic particle suspensions, the idea arose to replace standard single-core nanoparticles with nano-sized clusters of single-domain nanoparticles (grains) rigidly bound together by solid polymer matrix - multicore magnetic nanoparticles (MMNPs). To pursue this idea, a profound understanding of the MMNP interactions and self-assembly is required. In this work we present a computational study of the MMNP suspensions and elucidate their self-assembly and magnetic susceptibility. We show that depending on the magnetic moment of individual grains the suspensions exhibit qualitatively distinct regimes. Firstly, if the grains are moderately interacting, they contribute to a significant decrease of the remanent magnetisation of MMNPs and as such to a decrease of the magnetic susceptibility, this way confirming previous findings. If the grains are strongly interacting, instead, they serve as anchor points and support formation of grain clusters that span through several MMNPs, leading to MMNP cluster formation and a drastic increase of the initial magnetic response. Both the topology of the clusters and their size distribution in MMNP suspensions is found to be notably different from those formed in conventional magnetic fluids or magnetorheological suspensions.

AB - The necessity to improve magnetic building blocks in magnetic nano-structured soft materials stems from a fascinating potential these materials have in bio-medical applications and nanofluidics. Along with practical reasons, the interplay of magnetic and steric interactions on one hand, and entropy, on the other, makes magnetic soft matter fundamentally challenging. Recently, in order to tailor magnetic response of the magnetic particle suspensions, the idea arose to replace standard single-core nanoparticles with nano-sized clusters of single-domain nanoparticles (grains) rigidly bound together by solid polymer matrix - multicore magnetic nanoparticles (MMNPs). To pursue this idea, a profound understanding of the MMNP interactions and self-assembly is required. In this work we present a computational study of the MMNP suspensions and elucidate their self-assembly and magnetic susceptibility. We show that depending on the magnetic moment of individual grains the suspensions exhibit qualitatively distinct regimes. Firstly, if the grains are moderately interacting, they contribute to a significant decrease of the remanent magnetisation of MMNPs and as such to a decrease of the magnetic susceptibility, this way confirming previous findings. If the grains are strongly interacting, instead, they serve as anchor points and support formation of grain clusters that span through several MMNPs, leading to MMNP cluster formation and a drastic increase of the initial magnetic response. Both the topology of the clusters and their size distribution in MMNP suspensions is found to be notably different from those formed in conventional magnetic fluids or magnetorheological suspensions.

UR - https://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=tsmetrics&SrcApp=tsm_test&DestApp=WOS_CPL&DestLinkType=FullRecord&KeyUT=001003303700001

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U2 - 10.1039/D3SM00440F

DO - 10.1039/D3SM00440F

M3 - Article

VL - 19

SP - 4549

EP - 4561

JO - Soft Matter

JF - Soft Matter

SN - 1744-683X

IS - 24

ER -

ID: 40641240