Volume 45 Issue 1
Aug.  2015
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Yangguang XU, Xinglong GONG, Qiang WAN, Taixiang LIU, Shouhu XUAN. Magneto-sensitive smart soft material and magnetorheological mechanism[J]. Advances in Mechanics, 2015, 45(1): 201508. doi: 10.6052/1000-0992-15-010
Citation: Yangguang XU, Xinglong GONG, Qiang WAN, Taixiang LIU, Shouhu XUAN. Magneto-sensitive smart soft material and magnetorheological mechanism[J]. Advances in Mechanics, 2015, 45(1): 201508. doi: 10.6052/1000-0992-15-010

Magneto-sensitive smart soft material and magnetorheological mechanism

doi: 10.6052/1000-0992-15-010
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  • Corresponding author: Xinglong GONG
  • Received Date: 2015-03-02
  • Rev Recd Date: 2015-06-10
  • Publish Date: 2015-08-30
  • Magneto-sensitive smart soft materials are a class of multi-functional compos-ite materials prepared by dispersing micrometer or nanometer sized magnetic particles into di®erent carrier matrix. As external magnetic field may control the rheological properties in a continuous, rapid and reversible manner, these materials have wide applications in con-struction, vibration control, automotive industry, etc. In this paper, we first introduce the history and classification of magneto-sensitive smart soft materials, and analyze the charac-teristics and existing scientific issues for di®erent kinds of such materials. Then we discuss the state-of-the-art for experimental and theoretical studies of the magnetorheological mech-anism. Finally, we propose some future trends in this smart material development aiming at practical applications.

     

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  • [1]
    陈琳. 2009. 磁流变弹性体的研制及其力学性能的表征. [博士论文]. 合肥: 中国科学技术大学(Chen L. 2009. The development and mechanical characterization of magnetorheological elastomers. [PhD Thesis]. Hefei: University of Science and Technology of China).
    [2]
    杜善义, 冷劲松, 王殿富. 2001. 智能材料系统和结构. 北京: 科学出版社(Du S Y, Leng J S, Wang D F. 2001. The systems and structures of smart materials. Beijing: Science Press).
    [3]
    郭朝阳. 2013. 磁流变液法向力及减震器研究. [博士论文]. 合肥: 中国科学技术大学(Guo C Y. 2013.Study on normal force of magnetorheological fluid and magnetorheological damper. [PhD Thesis]. Hefei:University of Science and Technology of China).
    [4]
    姜德生, Richard O C. 2000. 智能材料器件结构与应用. 武汉: 武汉工业大学出版社(Jiang D S, Richard O C. 2000. Structures and applications of intelligent material. Wuhan: Wuhan University of Technology Press).
    [5]
    姚康德, 成国祥. 2002. 智能材料. 北京: 化学工业出版社(Yao K D, Cheng G X. 2002. Smart Materials. Beijing: Chemical Industrial Press).
    [6]
    赵晓鹏, 尹剑波. 2011. 电场调控的智能软材料. 北京: 科学出版社(Zhao X P, Yin J B. 2010. Smart soft materials tuned by electric fields. Beijing: Science Press).
    [7]
    An H N, Picken S J, Mendes E. 2010. Enhanced hardening of soft self-assembled copolymer gels under homogeneous magnetic fields. Soft Matter, 6: 4497-4503.
    [8]
    An H N, Picken S J, Mendes E. 2012a. Nonlinear rheological study of magneto responsive soft gels. Polymer, 53: 4164-4170.
    [9]
    An H N, Picken S J, Mendes E. 2012b. Direct observation of particle rearrangement during cyclic stress hardening of magnetorheological gels. Soft Matter, 8: 11995-12001.
    [10]
    An H N, Sun B, Picken S J, Mendes E. 2012c. Long time response of soft magnetorheological gels. Journal of Physical Chemistry B, 116: 4702-4711.
    [11]
    Andre S, Matthias M, Gareth J M, Mikhail S. 2013. Evaluation of highly compliant magneto-active elas-tomers with colossal magnetorheological response. Journal of Applied Polymer Science, 131: 39793 (1-7).
    [12]
    Bednarek S. 1999. The giant magnetostriction in ferromagnetic composites within an elastomer matrix.Applied Physics A-Materials Science & Processing, 68: 63-67.
    [13]
    Bell R C, Karli J O, Vavreck A N, Zimmerman D T, Ngatu G T, Wereley N M. 2008. Magnetorheology of submicron diameter iron microwires dispersed in silicone oil. Smart Materials and Structures, 17: 015028.
    [14]
    Bellan C, Bossis G. 2002. Field dependence of viscoelastic properties of MR elastomers. International
    [15]
    Journal of Modern Physics B, 16: 2447-2453.
    [16]
    Bica I. 2009. Electroconductive magnetorheological suspensions: production and physical processes. Journal of Industrial and Engineering Chemistry, 15: 233-237.
    [17]
    Bica I. 2011. Magnetoresistor sensor with magnetorheological elastomers. Journal of Industrial and Engi-neering Chemistry, 17: 83-89.
    [18]
    Blom P, Kari L. 2008. Smart audio frequency energy flow control by magneto-sensitive rubber isolators.Smart Materials and Structures, 17: 015043.
    [19]
    Boczkowska A, Awietjan S F. 2009. Smart composites of urethane elastomers with carbonyl iron. Journal of Materials Science, 44: 4104-4111.
    [20]
    Boczkowska A, Awietjan S F, Wroblewski R. 2007. Microstructure-property relationships of urethane mag-netorheological elastomers. Smart Materials and Structures, 16: 1924-1930.
    [21]
    Bossis G, Abbo C, Cutillas S, Lacis S, Metayer C. 2001. Electroactive and electrostructured elastomers.International Journal of Modern Physics B, 15: 564-573.
    [22]
    Bossis G, Lemaire E, Volkova O, Clercx H. 1997. Yield stress in magnetorheological and electrorheological fluids: a comparison between microscopic and macroscopic structural models. Journal of Rheology, 41: 687-704.
    [23]
    Bossis G, Volkova O, Lacis S, Meunier A. 2002. Magnetorheology: fluids, structures and rheology. Lecture Notes in Physics, 594: 202-230.
    [24]
    Bustamante R, Dorfmann A, Ogden R W. 2008. On variational formulations in nonlinear magnetoelasto-statics. Mathematics and Mechanics of Solids, 13: 725-745.
    [25]
    Byrom J, Biswal S L. 2013. Magnetic field directed assembly of two-dimensional fractal colloidal aggregates.Soft Matter, 9: 9167-9173.
    [26]
    Carlson J D, Catanzarite D M, Stclair K A. 1995. Commercial magnetorheological fluid devices. Proceeding of the 5th International Conference on ER Fluid, MR fluid and Associate Technology, 20-28.
    [27]
    Carlson J D, Jolly M R. 2000. MR fluid, foam and elastomer devices. Mechatronics, 10: 555-569.
    [28]
    Castaneda P P, Galipeau E. 2011. Homogenization-based constitutive models for magnetorheological elas-tomers at finite strain. Journal of the Mechanics and Physics of Solids, 59: 194-215.
    [29]
    Claracq J, Sarrazin J, Montfort J P. 2004. Viscoelastic properties of magnetorheological fluids. Rheologica Acta, 43: 38-49.
    [30]
    Chen L, Gong X L, Li W H. 2007. Microstructures and viscoelastic properties of anisotropic magnetorheo-logical elastomers. Smart Materials and Structures, 16: 2645-2650.
    [31]
    Chen L, Gong X L, Li W H. 2008. E®ect of carbon black on the mechanical performances of magnetorheo-logical elastomers. Polymer Testing, 27: 340-345.
    [32]
    Chen L, Gong X L, Jiang W Q, Yao J J, Deng H X, Li W H. 2007. Investigation on magnetorheological elastomers based on natural rubber. Journal of Materials Science, 42: 5483-5489.
    [33]
    Chen L, Jerrams S. 2011. A rheological model of the dynamic behavior of magnetorheological elastomers.Journal of Applied Physics, 110: 013513.
    [34]
    Chertovich A V, Stepanov G V, Kramarenko E Y, Khokhlov A R. 2010. New composite elastomers with giant magnetic response. Macromolecular Materials and Engineering, 295: 336-341.
    [35]
    Chin B D, Park J H, Kwon M H, Park O O. 2001. Rheological properties and dispersion stability of magnetorheological (MR) suspensions. Rheologica Acta, 40: 211-219.
    [36]
    Cho M S, Lim S T, Jang I B, Choi H J, Jhon M S. 2004. Encapsulation of spherical iron-particle withPMMA and its magnetorheological particles. IEEE Transactions on Magnetics, 40: 3036-3038.
    [37]
    Choi H J, Park B J, Cho M S, You J L. 2007. Core-shell structured poly (methyl methacrylate) coated carbonyl iron particles and their magnetorheological characteristics. Journal of Magnetism and Magnetic Materials, 310: 2835-2837.
    [38]
    Choi H J, Park B O, Park B J, Hato M J. 2011. Soft magnetic carbonyl iron microsphere dispersed in grease and its rheological characteristics under magnetic field. Colloid and Polymer Science, 289: 381-386.
    [39]
    Choi J S, Park B J, Cho M S, Choi H J. 2006. Preparation and magnetorheological characteristics of polymer coated carbonyl iron suspensions. Journal of Magnetism and Magnetic Materials, 304: E374-E376.
    [40]
    Coquelle E, Bossis G. 2006. Mullins e®ect in elastomers filled with particles aligned by a magnetic field.International Journal of Solids and Structures, 43: 7659-7672.
    [41]
    Danas K, Kankanala S V, Triantafykkidis N. 2012. Experiments and modeling of iron-particle-filled magne-torheological elastomers. Journal of the Mechanics and Physics of Solids, 60: 120-138.
    [42]
    Davis L C. 1999. Model of magnetorheological elastomers. Journal of Applied Physics, 85: 3348-3351.
    [43]
    De Vicente J, Ruiz-Lopez J A, Andablo-Reyes E, Segovia-Gutierrez J P, Hidalgo-Alvarez R. 2011a. Squeeze flow magnetorheology. Journal of Rheology, 55: 753-779.
    [44]
    De Vicente J, Klingenberg D J, Hidalgo-Alvarez R. 2011b. Magnetorheological fluids: a review. Soft Matter,7: 3701-3710.
    [45]
    De Vicente J, Lopez-Lopez M T, Gonzalez-Caballero F, Duran J D G. 2003. Rheological study of the stabilization of magnetizable colloidal suspensions by addition of silica nanoparticles. Journal of Rheology, 47: 1093-1109.
    [46]
    Deng H X, Gong X L, Wang L H. 2006. Development of an adaptive tuned vibration absorber with magne-torheological elastomer. Smart Materials and Structures, 15: N111-N116.
    [47]
    Donado F, Carrillo J L, MendozaME. 2002. Sound propagation in magneto-rheological suspensions. Journal of Physics-Condensed Matter, 14: 2153-2157.
    [48]
    Fang F F, Choi H J. 2007. Polymeric nanobead coated carbonyl iron particles and their magnetic property.Physica Status Solidi A-Applications and Materials Science, 204: 4190-4193.
    [49]
    Fang F F, Choi H J, Seo Y. 2010. Sequential coating of magnetic carbonyliron particles with polystyrene and multiwalled carbon nanotubes and its e®ect on their magnetorheology. ACS-Applied Materials &Interfaces, 2: 54-60.
    [50]
    Fang F F, Kim J H, Choi H J. 2009. Synthesis of core-shell structured PS/Fe3O4 microbeads and their magnetorheology. Polymer, 50: 2290-2293.
    [51]
    Fang F F, Liu Y D, Choi H J, Seo Y. 2011. Core-shell structured carbonyl iron microspheres prepared via dual-step functionality coatings and their magnetorheological response. ACS-Applied Materials &Interfaces, 3: 3487-3495.
    [52]
    Farjoud A, Caver R, Ahmadian M, Craft M. 2009. Magnetorheological fluid behavior in squeeze mode.Smart Materials and Structures, 18: 095001.
    [53]
    Farjoud A, Craft M, Burke W, Ahmadian M. 2011. Experimental investigation of MR squeeze mounts.Journal of Intelligent Material Systems and Structures, 22: 1645-1652.
    [54]
    Farjoud A, Mahmoodi N, Ahmadian M. 2012. Nonlinear model of squeeze flow of fluids with yield stress using perturbation techniques. Modern Physics Letters B, 26: 1150040.
    [55]
    Farshad M, Le Roux M. 2004. A new active noise abatement barrier system. Polymer Testing, 23: 855-860.
    [56]
    Fuchs A, Hu B, Gordaninejad F, Evrensel C. 2005. Synthesis and characterization of magnetorheological polyimide gels. Journal of Applied Polymer Science, 98: 2402-2413.
    [57]
    Fuchs A, Xin M, Gordaninejad F, Wang X J, Hitchcock G H, Gecol H, Evrensel C, Korol G. 2004. Develop-ment and characterization of hydrocarbon polyol polyurethane and silicone magnetorheological polymeric gels. Journal of Applied Polymer Science, 92: 1176-1182.
    [58]
    Fuchs A, Zhang Q, Elkins J, Gordaninejad F, Evrensel C. 2007. Development and characterization of magnetorheological elastomers. Journal of Applied Polymer Science, 105: 2497-2508.
    [59]
    Fuhrer R, Athanassiou E K, Luechinger N A, Stark W J. 2009. Crosslinking metal nanoparticles into the polymer backbone of hydrogels enables preparation of soft, magnetic field-driven actuators with muscle-like flexibility. Small, 5: 383-388.
    [60]
    Furukawa M, Mitsui Y, Fukumaru T, Kojio K. 2005. Microphase-separated structure and mechanical proper-ties of novel polyurethane elastomers prepared with ether based diisocyanate. Polymer, 46: 10817-10822.
    [61]
    Galipeau E, Castaneda P P. 2013. A finite-strain constitutive model for magnetorheological elastomers: magnetic torques and fiber rotations. Journal of the Mechanics and Physics of Solids, 61: 1065-1090.
    [62]
    Ginder J M, Clark S M, Schlotter W F, Nichols M E. 2002. Magnetostrictive phenomena in magnetorheo-logical elastomers. International Journal of Modern Physics B, 16: 2412-2418.
    [63]
    Ginder J M, Davis L C, Elie L D. 1996. Rheology of magnetorheological fluids: models and measurements.International Journal of Modern Physics B, 10: 3293-3303.
    [64]
    Ginder J M, Nichols M E, Elie L D, Clark S M. 2000. Controllable-sti®ness components based on magne-torheological elastomers. Proceedings of SPIE, Smart Structures and Materials 2000: Smart Structures and Integrated Systems, Newport Beach, CA, March 06, 2000. Bellingham WA: SPIE.
    [65]
    Ginder J M, Schlotter W F, Nichols M E. 2001. Magnetorheological elastomers in tunable vibration ab-sorbers. Smart Structures and Materials 2001: Damping and Isolation, 4331: 103-110.
    [66]
    Gollwitzer C, Krekhova M, Lattermann G, Rehberg I, Richter R. 2009. Surface instabilities and magnetic soft matter. Soft Matter, 5: 2093-2100.
    [67]
    Gong Q C, Wu J K, Gong X L, Fan Y C, Xia H S. 2013. Smart polyurethane foam with magnetic field controlled modulus and anisotropic compression property. RSC Advances, 3: 3241-3248.
    [68]
    Gong X L, Chen L, Li J F. 2007. Study of utilizable magnetorheological elastomers. International Journal of Modern Physics B, 21: 4875-4882.
    [69]
    Gong X L, Liao G J, Xuan S H. 2012a. Full-field deformation of magnetorheological elastomer under uniform magnetic field. Applied Physics Letters, 100: 211909.
    [70]
    Gong X L, Xu Y G, Xuan S H, Guo C Y, Zong, L H, JiangWQ. 2012b. The investigation on the nonlinearity of plasticine-like magnetorheological material under oscillatory shear rheometry. Journal of Rheology, 56: 1375-1391.
    [71]
    Gong X L, Zhang X Z, Zhang P Q. 2005. Fabrication and characterization of isotropic magnetorheological elastomers. Polymer Testing, 24: 669-676.
    [72]
    Guan X C, Dong X F, Ou J P. 2008. Magnetostrictive e®ect of magnetorheological elastomer. Journal of Magnetism and Magnetic Materials, 320: 158-163.
    [73]
    Guerrero-Sanchez C, Lara-Ceniceros T, Jimenez-Regalado E, Rasa M, Schubert U S. 2007. Magnetorheo-logical fluids based on ionic liquids. Advanced Materials, 19: 1740-1747.
    [74]
    Guo C Y, Gong X L, Xuan S H, Qin L J, Fan Y C. 2013. Squeeze behavior of magnetorheological fluids under constant volume and uniform magnetic field. Smart Materials and Structures, 22: 045020.
    [75]
    Heine M C, De Vicente J, Klingenberg D J. 2006. Thermal transport in sheared electro-and magnetorheo-logical fluids. Physics of Fluids, 18: 023301.
    [76]
    Holm C, Weis J J. 2005. The structure of ferrofluids: a status report. Current Opinion in Colloid and Interface Science, 10: 133-140.
    [77]
    Hong W, Han Y, Faidley L. 2011. Coupled magnetic field and viscoelasticity of ferrogel. International Journal of Applied Mechanics, 3: 259-278.
    [78]
    Hu B, Fuchs A, Huseyin S, Gordaninejad F, Evrensel C. 2006. Supramolecular magnetorheological polymer gels. Journal of Applied Polymer Science, 100: 2464-2479.
    [79]
    Iglesias G R, Lopez-Lopez M T, Duran J D G, González-Caballero F, Delgado A V. 2012. Dynamic char-acterization of extremely bidisperse magnetorheological fluids. Journal of Colloid & Interface Science, 377: 153-159.
    [80]
    Jang I B, Kim H B, Lee J Y, You J L, Choi H J, Jhon M S. 2005. Role of organic coating on carbonyl iron suspended particles in magnetorheological fluids. Journal of Applied Physics, 97: 10Q912.
    [81]
    Jolly M R, Bender J W, Carlson J D. 1999. Properties and applications of commercial magnetorheological fluids. Journal of Intelligent Material Systems and Structures, 10: 5-13.
    [82]
    Jolly M R, Carlson J D, Munoz B C. 1996. A model of the behaviour of magnetorheological materials.Smart Materials and Structures, 5: 607-614.
    [83]
    Jolly M R, Carlson J D, Munoz B C, Bullions, T A. 1996. The magnetoviscoelastic response of elastomer composites consisting of ferrous particles embedded in a polymer matrix. Journal of Intelligent Material Systems and Structures, 7: 613-622.
    [84]
    Kaleta J, Lewandowski D. 2007. Inelastic properties of magnetorheological composites: I. fabrication, ex-perimental tests, cyclic shear properties. Smart Materials and Structures, 16: 1948-1953.
    [85]
    Kallio M, Lindroos T, Aalto S, Jarvinen E, Karna T, Meinander T. 2007. Dynamic compression testing of a tunable spring element consisting of a magnetorheological elastomer. Smart Materials and Structures, 16: 506-514.
    [86]
    Kchit N, Lancon P, Bossis G. 2009. Thermoresistance and giant magnetoresistance of magnetorheological elastomers. Journal of Physics D-Applied Physics, 42: 105506.
    [87]
    Klingenberg D J. 2001. Magnetorheology: applications and challenges. Aiche Journal, 47: 246-249.
    [88]
    Klingenberg D J, Ulicny J C, Golden M A. 2007. Mason numbers for magnetorheology. Journal of Rheology, 51: 883-893.
    [89]
    Kuzhir P, Magnet C, Bossis G, Meunier A, Bashtovoi V. 2011. Rotational di®usion may govern the rheology of magnetic suspensions. Journal of Rheology, 55: 1297-1318.
    [90]
    Kono A, Shimizu K, Nakano H, Goto Y, Kobayashi Y, Ougizawa T, Horibe H. 2012. Positive-temperature-coefficient e®ect of electrical resistivity below melting point of poly (vinylidene fluoride) (PVDF) in Ni particle-dispersed PVDF composites. Polymer, 53: 1760-1764.
    [91]
    Koo J H, Khan F, Jang D D, Jung H J. 2010. Dynamic characterization and modeling of magneto-rheological elastomers under compressive loadings. Smart Materials and Structures, 19: 117002.
    [92]
    Kordonski W, Golini D. 2002. Multiple application of magnetorheological e®ect in high precision finishing.Journal of Intelligent Material Systems and Structures, 13: 401-404.
    [93]
    Lee C H, Jang M G. 2011. Virtual surface characteristics of a tactile display using magneto-rheological fluids. Sensors, 11: 2845-2856.
    [94]
    Leng J S, Lan X, Liu Y J, Du S Y, Huang W M, Liu N, Phee S J, Yuan Q. 2008. Electrical conductivity of thermoresponsive shape-memory polymer with embedded micron sized Ni powder chains. Applied Physics Letters, 92: 014104.
    [95]
    Li J F, Gong X L, Zhu H, Jiang W Q. 2009. Influence of particle coating on dynamic mechanical behaviors of magnetorheological elastomers. Polymer Testing, 28: 331-337.
    [96]
    Li W H, Du H, Chen G, Yeo S H, Guo N Q. 2001. Viscoelastic properties of MR fluids under oscillatory shear. Smart Structures and Materials 2001: Damping and Isolation, 4331: 333-342.
    [97]
    LiWH, Du H, Chen G, Yeo S H. 2002. Experimental investigation of creep and recovery behaviors of magne-torheological fluids. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing, 333: 368-376.
    [98]
    Li W H, Zhou Y, Tian T F, Alici G. 2010. Creep and recovery behaviors of magnetorheological elastomers.Frontiers of Mechanical Engineering in China, 5: 341-346.
    [99]
    Li Y H, Huang G Y, Zhang X H, Li B Q, Chen Y M, Lu T L, Lu T J, Xu F. 2013. Magnetic hydrogels and their potential biomedical applications. Advanced Functional Materials, 23: 660-672.
    [100]
    Liao G J, Gong X L, Kang C J, Xuan S H. 2011. The design of an active-adaptive tuned vibration absorber based on magnetorheological elastomer and its vibration attenuation performance. Smart Materials and Structures, 20: 075015.
    [101]
    Lim S T, Cho M S, Jang I B, Choi H J, Jhon M S. 2004. Magnetorheology of carbonyl-iron suspensions with submicron-sized filler. IEEE Transactions on Magnetics, 40: 3033-3035.
    [102]
    Lim S T, Cho M S, Jang I B, Choi H J. 2004. Magnetorheological characterization of carbonyl iron based suspension stabilized by fumed silica. Journal of Magnetism and Magnetic Materials, 282: 170-173.
    [103]
    Lim S T, Choi H J, Jhon M S. 2005. Magnetorheological characterization of carbonyl iron-organoclay suspensions. IEEE Transactions on Magnetics, 41: 3745-3747.
    [104]
    Liu J, Flores G A, Sheng R S. 2001. In-vitro investigation of blood embolization in cancer treatment using magnetorheological fluids. Journal of Magnetism and Magnetic Materials, 225: 209-217.
    [105]
    Liu T X, Xu Y G, Gong X L, Pang H M, Xuan S H. 2013a. Magneto-induced normal stress of magnetorhe-ological plastomer. AIP Advances, 3: 082122.
    [106]
    Liu T X, Gong X L, Xu Y G, Xuan S H. 2013b. Simulation of magneto-induced rearrangeable microstructures of magnetorheological plastomers. Soft Matter, 9: 10069-10080.
    [107]
    Liu T X, Gong X L, Xu Y G, Xuan S H. 2014. Magneto-induced stress enhancing e®ect in colloidal suspension of paramagnetic and superparamagnetic particles dispersed in a ferrofluid medium. Soft Matter, 10: 813 -818.
    [108]
    Liu T Y, Hu S H, Liu T Y, Liu D M, Chen S Y. 2006. Magnetic-sensitive behavior of intelligent ferrogels for controlled release of drug. Langmuir, 22: 5974-5978.
    [109]
    Lloyd J R, Hayesmichel M O, Radcli®e C J. 2007. Internal organizational measurement for control of magnetorheological fluid properties. Journal of Fluids Engineering-Transactions of the ASME, 129: 423-428.
    [110]
    Lokander M, Stenberg B. 2003a. Performance of isotropic magnetorheological rubber materials. PolymerTesting, 22: 245-251.
    [111]
    Lokander M, Stenberg B. 2003b. Improving the magnetorheological e®ect in isotropic magnetorheological rubber materials. Polymer Testing, 22: 677-680.
    [112]
    Lopez-Lopez M T, Gomez-Ramirez A, Rodriguez-Arco L, Durán J D G, Iskakova L, Zubarev A. 2012.Colloids on the frontier of ferrofluids. rheological properties. Langmuir, 28: 6232-6245.
    [113]
    Lopez-Lopez M T, Vertelov G, Bossis G, Kuzhir P, Duran J D G. 2007. New magnetorheological fluids based on magnetic fibers. Journal of Materials Chemistry, 17: 3839-3844.
    [114]
    Maranville C W, Ginder J M. 2005. Small-strain dynamic mechanical behavior of magnetorheological fluids entrained in foams. International Journal of Applied Electromagnetics and Mechanics, 22: 25-38.
    [115]
    Mazlan S A, Ekreem N B, Olabi A G. 2008a. An investigation of the behaviour of magnetorheological fluids in compression mode. Journal of Materials Processing Technology, 201: 780-785.
    [116]
    Mazlan S A, Issal A, Olabi A G. 2008b. Magnetorheological fluids behaviour in tension loading mode.Advanced Materials Research, 47-50: 242-245.
    [117]
    Mietta J L, Ruiz M M, Antonel P S, PerezO E, Butera A, Jorge G, Negri R M. 2012. Anisotropic magnetore-sistance and piezoresistivity in structured Fe3O4-silver particles in PDMS elastomers at room temperature.Langmuir, 28: 6985-6996.
    [118]
    Mitsumata T, Abe N. 2009a. Magnetic-field sensitive gels with wide modulation of dynamic modulus.Chemistry Letters, 38: 922-923.
    [119]
    Mitsumata T, Abe N. 2011. Giant and reversible magnetorheology of carrageenan/iron oxide magnetic gels.Smart Materials and Structures, 20: 124003.
    [120]
    Mitsumata T, Honda A, Kanazawa H, Kawai, M. 2012. Magnetically tunable elasticity for magnetic hy-drogels consisting of carrageenan and carbonyl iron particles. Journal of Physical Chemistry B, 116: 12341-12348.
    [121]
    Mitsumata T, Kosugi Y, Ouchi S. 2009b. E®ect of particles alignment on giant reduction in dynamic modulus of hydrogels containing needle-shaped magnetic particles. Progress on Colloid and Polymer Science, 136: 163-170.
    [122]
    Mitsumata T, Ohori S. 2011. Magnetic polyurethane elastomers with wide range modulation of elasticity.Polymer Chemistry, 2: 1063-1067.
    [123]
    Mitsumata T, Wakabayashi T, Okazaki T. 2008. Particle dispersibility and giant reduction in dynamic modulus of magnetic gels containing barium ferrite and iron oxide particles. Journal of Physical ChemistryB, 112: 14132-14139.
    [124]
    Nguyen V Q, Ahmed A S, Ramanujan R V. 2012. Morphing soft magnetic composites. Advanced Materials, 24: 4041-4054.
    [125]
    Olabi A G, Grunwald A. 2007. Design and application of magneto-rheological fluid. Materials & Design, 28: 2658-2664.
    [126]
    Park B J, Fang F F, Choi H J. 2010. Magnetorheology: materials and application. Soft Matter, 6: 5246-5253.
    [127]
    Phule P P. 1998. Synthesis of level magnetorheological fluids. MRS Bull, 23: 23-25.
    [128]
    Phule P P, Mihalcin M P, Genc S. 1999. The role of the dispersed-phase remnant magnetization on the redispersibility of magnetorheological fluids. Journal of Materials Research, 14: 3037-3041.
    [129]
    Rao P V, Maniprakash S, Srinivasan S M, Srinivasa A R. 2010. Functional behavior of isotropic magne-torheological gels. Smart Materials and Structures, 19: 085019.
    [130]
    Rinaldi C, Chaves A, Elborai S, He X W, Zahn M. 2005. Magnetic fluid rheology and flows. Current Opinion in Colloid & Interface Science, 10: 141-157.
    [131]
    Rosensweig R E. 1997. Ferrohydrodynamics. New York: Dover publications.
    [132]
    Rudykh S, Bertoldi K. 2013. Stability of anisotropic magnetorheological elastomers in finite deformations: a micromechanical approach. Journal of the Mechanics and Physics of Solids, 61: 949-967.
    [133]
    Ruiz-Lopez J A, Hidalgo-Alvarez R, De Vicente J. 2012. On the validity of continuous media theory for plastic materials in magnetorheological fluids under slow compression. Rheologica Acta, 51: 595-602.
    [134]
    Sahin H, Wang X J, Gordaninejad F. 2009. Temperature dependence of magneto-rheological materials.Journal of Intelligent Material Systems and Structures, 20: 2215-2222.
    [135]
    Sedlacik M, Pavlinek V, Saha P, ·Svrinová P, Filip P, Stejskal J. 2010. Rheological properties of magne-torheological suspensions based on core-shell structured polyaniline-coated carbonyl iron particles. SmartMaterials and Structures, 19: 115008.
    [136]
    See H, Chen R, Keentok M. 2004. The creep behaviour of a field-responsive fluid. Colloid and PolymerScience, 282: 423-428.
    [137]
    Shahrivar K, De Vicente J. 2013. Thermoresponsive polymer-based magneto-rheological (MR) composites as a bridge between MR fluids and MR elastomers. Soft Matter, 9: 11451-11456.
    [138]
    Shahrivar K, De Vicente J. 2014. Thermogelling magnetorheological fluids. Smart Materials and Structures, 23: 025012.
    [139]
    Shen Y, Golnaraghi M F, Heppler G R. 2004. Experimental research and modeling of magnetorheological elastomers. Journal of Intelligent Material Systems and Structures, 15: 27-35.
    [140]
    Shiga T, Okada A, Kurauchi T. 1995. Magnetroviscoelastic behavior of composite gels. Journal of AppliedPolymer Science, 58: 787-792.
    [141]
    Stepanov G V, Abramchuk S S, Grishin D A, Nikitin L V, Kramarenko E Y, Khokhlov A R. 2007. E®ect of a homogeneous magnetic field on the viscoelastic behavior of magnetic elastomers. Polymer, 48: 488-495.
    [142]
    Stepanov G V, Semerenko D A, Bakhtiiarov A V, Storozhenko P A. 2013. Magnetoresistive e®ect in magnetoactive elastomers. Journal of Superconductivity and Novel Magnetism, 26: 1055-1059.
    [143]
    Sun T L, Gong X L, Jiang W Q, Li J F, Xu Z B, Li W H. 2008. Study on the damping properties of magnetorheological elastomers based on cis-polybutadiene rubber. Polymer Testing, 27: 520-526.
    [144]
    Tian T F, Li W H, Deng Y M. 2011. Sensing capabilities of graphite based MR elastomers. Smart Materials and Structures, 20: 025022.
    [145]
    Tiraferri A, Chen K L, Sethi R, Elimelech M. 2008. Reduced aggregation and sedimentation of zero-valent iron nanoparticles in the presence of guar gum. Journal of Colloid and Interface Science, 324: 71-79.
    [146]
    Trendler A M, Bose H. 2005. Influence of particle size on the rheological properties of magnetorheological suspensions. Proceedings, Electrorheological Fluids and Magnetorheological Suspensions (ERMR 2004), 433-439.
    [147]
    Ulicny J C, Balogh M P, Potter N M,Waldo R A. 2007. Magnetorheological fluid durability test-iron analysis.Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing, 443: 16-24.
    [148]
    Varga Z, Filipcsei G, Zrinyi M. 2006. Magnetic field sensitive functional elastomers with tuneable elastic modulus. Polymer, 47: 227-233.
    [149]
    Wang H Y, Bi C, Zhang Z H, Kan J W, Gao C F. 2013. An investigation of tensile behavior of magnetorhe-ological fluids under di®erent magnetic fields. Journal of Intelligent Material Systems and Structures, 24: 541-547.
    [150]
    Wang X J, Gordaninejad F, Calgar M, Liu Y M, Sutrisno J, Fuchs A. 2009. Sensing behavior of magne-torheological elastomers. Journal of Mechanical Design, 131: 091004 (1-6).
    [151]
    Wei B, Gong X L, Jiang W Q. 2010a. Influence of polyurethane properties on mechanical performances of magnetorheological elastomers. Journal of Applied Polymer Science, 116: 771-778.
    [152]
    Wei B, Gong X L, Jiang W Q, Qin L J, Fan Y C. 2010b. Study on the properties of magnetorheological gel based on polyurethane. Journal of Applied Polymer Science, 118: 2765-2771.
    [153]
    Wereley N M, Chaudhuri A, Yoo J H, John S, Kotha S, Suggs A, Radhakrishnan R, Love B J, Sudarshan TS. 2006. Bidisperse magnetorheological fluids using Fe particles at nanometer and micron scale. Journal of Intelligent Material Systems and Structures, 17: 393-401.
    [154]
    Wilson M J, Fuchs A, Gordaninejad F. 2002. Development and characterization of magnetorheological polymer gels. Journal of Applied Polymer Science, 84: 2733-2742.
    [155]
    Wu J K, Gong X G, Chen L, Xia H S, Hu Z G. 2009. Preparation and characterization of isotropic polyurethane magnetorheological elastomer through in situ polymerization. Journal of Applied PolymerScience, 114: 901-910.
    [156]
    Wu J K, Gong X L, Fan Y C, Xia H S. 2010. Anisotropic polyurethane magnetorheological elastomer prepared through in situ polycondensation under a magnetic field. Smart Materials and Structures, 19: 105007.
    [157]
    Wu J K, Gong X L, Fan Y C, Xia H S. 2011. Physically crosslinked poly (vinyl alcohol) hydrogels with magnetic field controlled modulus. Soft Matter, 7: 6205-6212.
    [158]
    Wu J K, Gong X L, Fan Y C, Xia H S. 2012. Improving the magnetorheological properties of polyurethane magnetorheological elastomer through plasticization. Journal of Applied Polymer Science, 123: 2476-2484.
    [159]
    Xu Y G, Gong X L, Liu T X, Xuan S H. 2013. Magneto-induced microstructure characterization of magne-torheological plastomers using impedance spectroscopy. Soft Matter, 9: 7701-7709.
    [160]
    Xu Y G, Gong X L, Xuan S H, Li X F, Qin L J, Jiang W Q. 2012. Creep and recovery behaviors of magnetorheological plastomer and its magnetic-dependent properties. Soft Matter, 8: 8483-8492.
    [161]
    Xu Y G, Gong X L, Xuan S H, Zhang W, Fan Y C. 2011. A high-performance magnetorheological material: preparation, characterization and magnetic-mechanic coupling properties. Soft Matter, 7: 5246-5254.
    [162]
    Xu Y G, Liu T X, Gong X L, Xuan S H. 2014. Squeeze flow behaviors of magnetorheological plastomers under constant volume. Journal of Rheology, 58: 659-679.
    [163]
    Xu Z B, Gong X L, Liao G J, Chen X M. 2010. An Active-damping-compensated magnetorheological elastomer adaptive tuned vibration absorber. Journal of Intelligent Material Systems and Structures, 21: 1039-1047.
    [164]
    Xuan S H, Zhang Y L, Zhou Y F, Jiang W Q Gong X L. 2012. Magnetic Plasticine (TM): a versatile magnetorheological material. Journal of Materials Chemistry, 22: 13395-13400.
    [165]
    Yin H M, Sun L Z, Chen J S. 2006. Magneto-elastic modeling of composites containing chain-structured magnetostrictive particles. Journal of the Mechanics and Physics of Solids, 54: 975-1003.
    [166]
    York D, Wang X, Gordaninejad F. 2007. A new MR fluid-elastomer vibration isolator. Journal of IntelligentMaterial Systems and Structures, 18: 1221-1225.
    [167]
    Zajac P, Kaleta J, Lewandowski D, Gasperowicz, A. 2010. Isotropic magnetorheological elastomers with thermoplastic matrices: structure, damping properties and testing. Smart Materials and Structures, 19: 045014.
    [168]
    Zhang W, Gong X L, Jiang W Q, Fan Y C. 2010. Investigation of the durability of anisotropic magnetorhe-ological elastomers based on mixed rubber. Smart Materials and Structures, 19: 085008.
    [169]
    Zhang W, Gong X L, Xuan S H, Xu Y G. 2010. High-performance hybrid magnetorheological materials: preparation and mechanical properties. Industrial & Engineering Chemistry Research, 49: 12471-12476.
    [170]
    Zhou G Y. 2003. Shear properties of a magnetorheological elastomer. Smart Materials and Structures, 12: 139-146.
    [171]
    Zielinski T G, Rak M. 2010. Acoustic absorption of foams coated with MR fluid under the influence of magnetic field. Journal of Intelligent Material Systems and Structures, 21: 125-131.
    [172]
    Zrinyi M. 2000. Intelligent polymer gels controlled by magnetic fields. Colloid and Polymer Science, 278: 98-103.
    [173]
    Zubarev A Y. 2012. On the theory of the magnetic deformation of ferrogel. Soft Matter, 8: 3174-3179.
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