2018
DOI: 10.1007/s10853-018-2315-3
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Implementation of functionalized multiwall carbon nanotubes on magnetorheological elastomer

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Cited by 37 publications
(30 citation statements)
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“…The damping in the systems with weakly bonded interfaces is caused mainly due to internal friction between the particles and matrix and can be estimated based on Lavernia’s analysis [48]. Recently, it was found that this damping mechanism can be significantly improved by the incorporation of the functionalized carbon nanotubes (1 wt %) into the body of the MREs [49]. Finally, magnetism-induced damping is represented by the energy absorbed to overcome magnetic interactions between the particles [46] and can be modelled as presented by Jolly et al [50].…”
Section: Resultsmentioning
confidence: 99%
“…The damping in the systems with weakly bonded interfaces is caused mainly due to internal friction between the particles and matrix and can be estimated based on Lavernia’s analysis [48]. Recently, it was found that this damping mechanism can be significantly improved by the incorporation of the functionalized carbon nanotubes (1 wt %) into the body of the MREs [49]. Finally, magnetism-induced damping is represented by the energy absorbed to overcome magnetic interactions between the particles [46] and can be modelled as presented by Jolly et al [50].…”
Section: Resultsmentioning
confidence: 99%
“…Lee et al 319 described the preparation of MREs containing g-Fe 2 O 3 rod-shaped hard magnetic particles added to CIP to enhance the MR effect of MREs. Also, Borin et al 311 investigated the mechanical properties of MREs prepared by 265 CIP/CNT RTV silicone rubber B15 000/B30 000 : 40 Sphere/fibers Li and Zhang 305 CIP Silicone rubber B50 000/B5000 Spheres Nayak et al 306 CIP/carbon black RTV silicone elastomer B5000/unknown Sphere/unknown Kwon et al 307 CIP/maghemite Natural rubber B5000/B500:unknown Sphere/rod Shabdin et al 308 CIP/graphite Silicone rubber B6000/B16 000 Sphere/unknown Lu et al 309 CIP/carbon black Natural rubber B3200/unknown Sphere/unknown Fan et al 310 CIP/carbon black Natural rubber B3000/B100 Sphere/unknown Borin et al 311 CIP/NdFeB PDMS B5000/B35000 Spheres Aziz et al 312 CIP/MWCNT Natural rubber B6000/B10 000 : 10 Sphere/fibers Aziz et al 313 CIP/MWCNT Natural rubber B6000/B10 000 : 20 Sphere/fibers Poojary et al 314 CIP/CNT RTV silicone rubber B5000/B10 000 : 20 Sphere/fibers Sorokin et al 315 Fe/magnetite Silicon rubber 55 000/35 Spheres Aloui and Klüppel 316 CIP/iron oxide Styrene-butadiene rubber 3500/15 Spheres/irregular von Lockette et al 317 Iron/iron RTV silicone rubber 40 000/10 000 Unknown mixing soft and hard magnetic particles. Although the MR response is mainly governed by the (easily magnetizable) soft particles, values of E 0 and tan d in the on-state were larger when hard particles were pre-magnetized (see Fig.…”
Section: Experimental Techniquesmentioning
confidence: 99%
“…Furthermore, Fan [67] and Lu [68] respectively investigated the effect of carbon black size and content on properties of magnetoresponsive composite elastomers. Aziz et al [69,70] found that functional carboxylated multiwall carbon nanotubes had better compatibility with magnetic particles.…”
Section: Additivesmentioning
confidence: 99%