Review of current research progress related to magnetorheological elastomer material

Magnetorheological (MR) material started to gain exposure when researchers explore the potential of magnetic field-responsive material based on fluid (MRF), foam (MR foam), elastomer (MRE), and gel (MRG). Magnetorheological elastomer (MRE) is a smart material in which its physical properties can be...

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Autores principales: M.F. Jaafar, Faizal Mustapha, Mazli Mustapha
Formato: article
Lenguaje:EN
Publicado: Elsevier 2021
Materias:
MRE
CIP
Acceso en línea:https://doaj.org/article/12c2b90c2f66463a9ea81677a2326eb3
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spelling oai:doaj.org-article:12c2b90c2f66463a9ea81677a2326eb32021-11-10T04:27:43ZReview of current research progress related to magnetorheological elastomer material2238-785410.1016/j.jmrt.2021.10.058https://doaj.org/article/12c2b90c2f66463a9ea81677a2326eb32021-11-01T00:00:00Zhttp://www.sciencedirect.com/science/article/pii/S2238785421011947https://doaj.org/toc/2238-7854Magnetorheological (MR) material started to gain exposure when researchers explore the potential of magnetic field-responsive material based on fluid (MRF), foam (MR foam), elastomer (MRE), and gel (MRG). Magnetorheological elastomer (MRE) is a smart material in which its physical properties can be changed rapidly and reversibly under varying magnetic field strength. Due to the potential commercialization of MRE-based devices, the fundamental factors that affect the rheological and mechanical properties of MRE need to be identified and documented properly. Various factors such as ferromagnetic particles' condition, elastomer matrix's condition, strain amplitude, exciting frequency, temperature, and many more have been reviewed and presented with supporting figures highlighting the MRE's current findings. A collection of MRE-based devices is also presented to summarize the applications explored by current researchers. A few challenges in the MRE research require immediate attention. It includes designing an innovative MRE fabrication equipment incorporating an electromagnet to permit anisotropic particle configuration during crosslinking. Moreover, an optimum thickness of MRE needs to be studied in every MRE-based device design to ensure that the magnetic field is optimized thoroughly. Therefore, more studies ought to be done to improve the MRE that can enable the commercialization of MRE in various applications.M.F. JaafarFaizal MustaphaMazli MustaphaElsevierarticleMREMagnetorheological elastomerField-dependent compositeFerromagneticCarbonyl iron particleCIPMining engineering. MetallurgyTN1-997ENJournal of Materials Research and Technology, Vol 15, Iss , Pp 5010-5045 (2021)
institution DOAJ
collection DOAJ
language EN
topic MRE
Magnetorheological elastomer
Field-dependent composite
Ferromagnetic
Carbonyl iron particle
CIP
Mining engineering. Metallurgy
TN1-997
spellingShingle MRE
Magnetorheological elastomer
Field-dependent composite
Ferromagnetic
Carbonyl iron particle
CIP
Mining engineering. Metallurgy
TN1-997
M.F. Jaafar
Faizal Mustapha
Mazli Mustapha
Review of current research progress related to magnetorheological elastomer material
description Magnetorheological (MR) material started to gain exposure when researchers explore the potential of magnetic field-responsive material based on fluid (MRF), foam (MR foam), elastomer (MRE), and gel (MRG). Magnetorheological elastomer (MRE) is a smart material in which its physical properties can be changed rapidly and reversibly under varying magnetic field strength. Due to the potential commercialization of MRE-based devices, the fundamental factors that affect the rheological and mechanical properties of MRE need to be identified and documented properly. Various factors such as ferromagnetic particles' condition, elastomer matrix's condition, strain amplitude, exciting frequency, temperature, and many more have been reviewed and presented with supporting figures highlighting the MRE's current findings. A collection of MRE-based devices is also presented to summarize the applications explored by current researchers. A few challenges in the MRE research require immediate attention. It includes designing an innovative MRE fabrication equipment incorporating an electromagnet to permit anisotropic particle configuration during crosslinking. Moreover, an optimum thickness of MRE needs to be studied in every MRE-based device design to ensure that the magnetic field is optimized thoroughly. Therefore, more studies ought to be done to improve the MRE that can enable the commercialization of MRE in various applications.
format article
author M.F. Jaafar
Faizal Mustapha
Mazli Mustapha
author_facet M.F. Jaafar
Faizal Mustapha
Mazli Mustapha
author_sort M.F. Jaafar
title Review of current research progress related to magnetorheological elastomer material
title_short Review of current research progress related to magnetorheological elastomer material
title_full Review of current research progress related to magnetorheological elastomer material
title_fullStr Review of current research progress related to magnetorheological elastomer material
title_full_unstemmed Review of current research progress related to magnetorheological elastomer material
title_sort review of current research progress related to magnetorheological elastomer material
publisher Elsevier
publishDate 2021
url https://doaj.org/article/12c2b90c2f66463a9ea81677a2326eb3
work_keys_str_mv AT mfjaafar reviewofcurrentresearchprogressrelatedtomagnetorheologicalelastomermaterial
AT faizalmustapha reviewofcurrentresearchprogressrelatedtomagnetorheologicalelastomermaterial
AT mazlimustapha reviewofcurrentresearchprogressrelatedtomagnetorheologicalelastomermaterial
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