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The Dynamic Shear Modulus and Damping Ratio of Clay Nanocomposites

Published online by Cambridge University Press:  01 January 2024

Z. Nese Kurt*
Affiliation:
Ataturk University, Department of Civil Engineering, 25240 Erzurum, Turkey
Suat Akbulut
Affiliation:
Ataturk University, Department of Civil Engineering, 25240 Erzurum, Turkey
*
*E-mail address of corresponding author: [email protected]
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Abstract

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Clay soils are very useful as liners in geotechnical structures such as landfill sites, dams, water channels, etc. Swelling is a common problem in clay liners, however. To better understand swelling properties, in the present study clay nanocomposites were produced by means of the sol gel method, using a hydrophobic clay, polymers (locust bean gum, latex, glycerine, vinyl acrylic copolymer), and rubber powder. The study focused on the swelling and dynamic properties (secant shear modulus and damping ratio) of the clay nanocomposites researched experimentally in laboratory conditions. The dynamic tests were conducted on samples compacted using two different compaction energy levels. The test results were compared with those of natural clay and hydrophobic organo-clay. The test results revealed that the damping ratios and secant shear modulus of clay nanocomposites without rubber (CNC) and with rubber (CNCr) that were compacted with both the E1 and E2 energy levels were increased and decreased, respectively. In addition, with increasing percentage of vinyl acrylic in nanoclay composites, the secant shear modulus values were decreased and damping ratio values were increased. Consequently, the test results found that the swelling and dynamic properties of clay nanocomposites can be optimized in order to attenuate the negative effects of dynamic loads on clay liners.

Type
Article
Copyright
Copyright © Clay Minerals Society 2014

References

Aghaei Araei, A. Razeghi, H.R. Hashemi Tabatabaei, S. and Ghalandarzadeh, A., 2010 Dynamic properties of gravelly materials Transactions A: Civil Engineering 17 245261.Google Scholar
Akbulut, S. Arasan, S. and Kalkan, E., 2007 Modification of clayey soils using scrap tire rubber and synthetic fibers Applied Clay Science 38 2332.CrossRefGoogle Scholar
Akbulut, S. Kurt, Z.N. and Arasan, S., 2010 Electrokinetic properties of surfactant modified clays International Journal of Civil and Structural Engineering 1 354361.Google Scholar
Akbulut, S. Kurt, Z.N. and Arasan, S., 2012 Surfactant modified clays’ consistency limits and contact angles Earth Sciences Research Journal 16 1319.Google Scholar
Akbulut, S. Kurt, Z.N. Arasan, S. and Pekdemir, Y., 2013 Geotechnical properties of some organoclays Sadhana 38 317329.Google Scholar
Alexandre, M. and Dubois, P., 2000 Polymer-layered silicate nanocomposites: preparation, properties and uses of a new class of materials Materials Science and Engineering 28 163.CrossRefGoogle Scholar
Ashkezari, G.D. Aghakouchak, A.A. and Kokabi, M., 2008 Design, manufacturing and evaluation of the performance of steel like fiber reinforced elastomeric seismic isolators Journal of Materials Processing Technology 197 140150.CrossRefGoogle Scholar
ASTM D 1557, 2012 Standard Test Method for Laboratory Compaction Characteristics of Soil Using Modified Effort West Conshohocken, Pennsylvania, USA ASTM.Google Scholar
ASTM D 4546, 2008 Standard Test Methods for One-Dimensional Swell or Collapse of Cohesive Soils West Conshohocken, Pennsylvania, USA ASTM.Google Scholar
ASTM D 6528, 2007 Standard Test Method for Consolidated Undrained Direct Simple Shear Testing of Cohesive Soils West Conshohocken, Pennsylvania, USA ASTM.Google Scholar
Barmar, M. Kaffashi, B. and Barikani, M., 2010 Investigating the Uni-HEUR thickener performance considering hydrophilic segment length Colloids and Surfaces A: Physicochemical and Engineering Aspects 364 105108.CrossRefGoogle Scholar
Bate, B., 2010 Engineering behavior of fine-grained soils modified with a controlled organic phase PhD thesis Atlanta, USA Georgia Institute of Technology.Google Scholar
Bate, B. and Burns, S., 2012.Influencing factors on the dynamic properties of organobentonites Geo-Congress 2012, Oakland, California, USACrossRefGoogle Scholar
Burmistr, M.V. Sukhyy, K.M. Shilov, V.V. Pissis, P. Spanoudaki, A. Sukha, I.V. Tomilo, V.I. and Gomza, Y.P., 2005 Synthesis, structure, thermal and mechanical properties of nanocomposites based on linear polymers and layered silicates modified by polymeric quaternary ammonium salts (ionenes) Polymer 46 1222612232.CrossRefGoogle Scholar
Chaudhari, T.D. Thiagarajan, C. Theethira, P.K. Shuler, S. and Jaarda, E.J., 2005.Energy absorbing articles United States Patent Application Publication, US 2005/0287371 A1Google Scholar
Chung, D.D.L., 2003 Structural composite materials tailored for damping Journal of Alloys and Compounds 355 216223.CrossRefGoogle Scholar
D’Onofrio, A. Penna, A., Di Benedetto, H. Doanh, T. Geoffroy, H. and Sauzeat, C., 2003 Small strain behaviour of lime-treated silty sand Deformation Characteristics of Geomaterials Lisse, The Netherlands Swets & Zeitlinger 329336.Google Scholar
Darendeli, M.B., 2001 Development of a new family of normalized modulus reduction and material damping curves PhD thesis Texas, USA Faculty of the Graduate School of The University of Texas at Austin.Google Scholar
de Carvalho, A.J.F. Curvelo, A.A.S. and Agnelli, J.A.M., 2001 A first insight on composites of thermoplastic starch and kaolin Carbohydrate Polymers 45 189194.CrossRefGoogle Scholar
Dey, P. Maiti, S. and Sa, B., 2012 Locust bean gum and its application in pharmacy and biotechnology: an overwiew International Journal of Current Pharmaceutical Research 4 711.Google Scholar
Das, B.M., 1998 Principles of Geotechnical Engineering Boston, Massachusetts, USA PWS Publishing Company.Google Scholar
Finegan, I.C. and Gibson, R.F., 1999 Recent research on enhancement of damping in polymer composites Composite Structures 44 8998.CrossRefGoogle Scholar
Finegan, I.C. and Gibson, R.F., 2000 Analytical modeling of damping at micromechanical level in polymer composites reinforced with coated fibers Composites Science and Technology 60 10771084.CrossRefGoogle Scholar
Fischer, H., 2003 Polymer nanocomposites: from fundamental research to specific applications Materials Science and Engineering 23 763772.CrossRefGoogle Scholar
Geocomp, 2007 Cyclic Direct Simple Shear User’s Manual: Control and Report Sorftware for Fully Automated Cyclic Direct Simple Shear Tests on ShearTrac-II Systems Using MS-Windows® 2000 or XP Software, Version 5.0, Boxborough, Massachusetts, USA .Google Scholar
Hackman, I. and Hollaway, L., 2006 Epoxy-layered silicate nanocomposites in civil engineering Composites 37 11611170.CrossRefGoogle Scholar
Hamed, G.R., Gent, A.N., 2001 Materials and compounds Engineering with Rubber: How to Design Rubber Components Munich, Germany Carl Hanser, Verlag 1334.Google Scholar
Hbaieb, K. Wang, Q.X. Chia, Y.H.J. and Cotterell, B., 2007 Modelling stiffness of polymer/clay nanocomposites Polymer 48 901909.CrossRefGoogle Scholar
He, S.J. Wang, Y.Q. Wu, Y. P. Wu, X.H. Lu, Y.L. and Zhang, L.Q., 2010 Preparation, structure, performance, industrialisation and application of advanced rubber/clay nanocomposites based on latex compounding method Plastics RubberandComposites 39, 3342.Google Scholar
Kilar, V. and Koren, D., 2009 Seismic behaviour of asymmetric base isolated structures with various distributions of isolators Engineering Structures 31 910921.CrossRefGoogle Scholar
Koh, H.C. Park, J.S. Jeong, M.A. Hwang, H.Y. Hong, Y.T. Ha, S.Y. and Nam, S.Y., 2008 Preparation and gas permeation properties of biodegradable polymer/layered silicate nanocomposite membranes Desalination 233 201209.CrossRefGoogle Scholar
Kramer, S.L., 1996 Geotechnical Earthquake Engineering New Jersey, USA Prentice Hall.Google Scholar
Kumar, S.S. Krishna, A.M. and Dey, A., 2013 Parameters influencing dynamic soil properties: a review treatise National Conference on Recent Advances in Civil Engineering November 1516.Google Scholar
Kurt, Z.N., 2009 Investigation of the strength properties of surfactant modified clay Master Thesis Erzurum, Turkey Graduate School of Natural and Applied Sciences, Ataturk University.Google Scholar
Kyminas, S.C. Philips, J.C. and Einhaus, B.J., 1989.Coating for roof surfaces United States Patent Documents, 4.859.723Google Scholar
Lagaly, G., 1999 Introduction: from clay mineral-polymer interactions to clay mineral-polymer nanocomposites Applied Clay Science 15 19.Google Scholar
LeBaron, P.C. Wang, Z. and Pinnavaia, T.J., 1999 Polymer-layered silicate nanocomposites: an overview Applied Clay Science 15 1129.CrossRefGoogle Scholar
Lin, J.T. Jong, S.J. and Cheng, S., 1993 A new method for preparing microporous titanium pillared clays Microporous Materials 1 287290.CrossRefGoogle Scholar
Liu, P., 2007 Polymer modified clay minerals: A review Applied Clay Science 38 6476.CrossRefGoogle Scholar
Lopes da Silva, J.A. Gonçalves, M.P. and Rao, M.A., 1994 Influence of temperature on the dynamic and steady-shear rheology of pectin dispersions Carbohydrate Polymers 23 7787.CrossRefGoogle Scholar
Ludwigson, M.N. Swan, C.C. and Lakes, R.S., 2002 Damping and stiffness of particulate SiC-InSn composite Journal of Composite Materials 35 110.Google Scholar
Maier, M. Anderson, M. Karl, C. Magnuson, K., Whistley, R.L. and BeMiller, J.N., 1993 Guar, locust bean, tara, and fenugreek gums Industrial Gums: Polysaccharides and their Derivatives 3rd edition New York Academic Press 205213.Google Scholar
Majedi, P., 2013 Examination of some geotechnical and dynamic properties of hydrophobic clay that mixed by polymer Masters thesis, Graduate School of Natural and Applied Sciences Erzurum, Turkey Ataturk University.Google Scholar
Mishra, A.K. Bose, S. Kuila, T. Kim, N.H. and Lee, J.H., 2012 Silicate-based polymer-nanocomposite membranes for polymer electrolyte membrane fuel cells Progress in Polymer Science 37 842869.CrossRefGoogle Scholar
Mittal, V., 2009 Polymer layered silicate nanocomposites: a review Materials 2 9921057.CrossRefGoogle Scholar
Mohan, T.P. and Kanny, K., 2011 Water barrier properties of nanoclay filled sisal fibre reinforced epoxy composites Composites 42 385393.CrossRefGoogle Scholar
Moon, B.Y. Kang, G.J. Kang, B.S. and Kelly, J.M., 2002 Design and manufacturing of fiber reinforced elastomeric isolator for seismic isolation Journal of Materials Processing Technology 130-131 145150.CrossRefGoogle Scholar
Murphy, R.E.J. Haemer, L.F. and Scholl, E.C., 1977.Method for installing surface covering or the like United States Patent Documents, 4.036.673Google Scholar
Nakhaei, A. Marandi, S.M. Sani Kermani, S. and Bagheripour, M.H., 2012 Dynamic properties of granular soils mixed with granulated rubber Soil Dynamics and Earthquake Engineering 43 124132.CrossRefGoogle Scholar
Paiva, L.B. Morales, A.N. and Diaz, F.R.V., 2008 Organoclays: Properties, preparation and applications Applied Clay Science 42 824.CrossRefGoogle Scholar
Pavlidou, S. and Papaspyrides, C.D., 2008 A review on polymer-layered silicate nanocomposites Progress in Polymer Science 33 11191198.CrossRefGoogle Scholar
Petersson, L. and Oksman, K., 2006 Biopolymer based nanocomposites: comparing layered silicates and microcrystalline cellulose as nanoreinforcement Composites Science and Technology 66 21872196.CrossRefGoogle Scholar
Ray, S.S. and Okamoto, M., 2003 Polymer/layered silicate nanocomposites: a review from preparation to processing Progress in Polymer Science 28 15391641.Google Scholar
Rhim, J.W., 2011 Effect of clay contents on mechanical and water vapor barrier properties of agar-based nanocomposite films Carbohydrate Polymers 86 691699.CrossRefGoogle Scholar
Rivin, E.I., 2007.Use of stiffness/damping/natural frequency criteria in vibration control IFToMM World Congress Besanson, June 2–6Google Scholar
Schadler, L.S., Ajayan, P.M. Schadler, L.S. and Braun, P.V., 2003 Polymer-based and polymer-filled nanocomposites Nanocomposite Science and Technology Weinheim, Germany Wiley-VCH Verlag GmbH & Co. KGaA 77153.CrossRefGoogle Scholar
Tang, X. Alavi, S. and Herald, T.J., 2008 Effects of plasticizers on the structure and properties of starch-clay nanocomposite films Carbohydrate Polymers 74 552558.CrossRefGoogle Scholar
Tanniru, M. Yuan, Q. and Misra, R.D.K., 2006 On significant retention of impact strength in clay-reinforced high-density polyethylene (HDPE) nanocomposites Polymer 47 21332146.CrossRefGoogle Scholar
Tjong, S.C., 2006 Structural and mechanical properties of polymer nanocompos i tes Materials Science and Engineering 53 73197.CrossRefGoogle Scholar
Winkworth-Smith, C. and Foster, T.J. (2013) General Overview of Biopolymers: Structure, Properties, and Applications. Handbook of Biopolymer-Based Materials From Blends and Composites to Gels and Complex Networks (Thomas, S., Durand, D., Chassenieux, C., and Jyotishkumar, P., editors). Wiley-VHC Verlag GmbH&Co. KgaA, Weinheim, Germany.Google Scholar
Xu, Q. Pang, M. Zhu, L. Zhang, Y. and Feng, S., 2010 Mechanical properties of silicone rubber composed of diverse vinyl content silicone gums blending Materials and Design 31 40834087.CrossRefGoogle Scholar
Yasmin, A. Luo, J.J. and Daniel, I.M., 2006 Mechanical and thermal behavior of clay/epoxy nanocomposites Composites Science and Technology 66 24152422.CrossRefGoogle Scholar
Zare-Shahabadi, A. Shokuhfar, A. Ebrahimi-Nejad, S. Arjmand, M. and Termeh, M., 2011 Modeling the stiffness of polymer/layered silicate nanocomposites: More accurate predictions with consideration of exfoliation ratio as a function of filler content Polymer Testing 30 408414.CrossRefGoogle Scholar
Zhang, J. Andrus, R.D. and Juang, C.H., 2005 Normalized shear modulus and material damping ratio relationships Journal of Geotechnical and Geoenvironmental Engineering 453464.CrossRefGoogle Scholar
Zhu, L. and Wool, R.P., 2006 Nanoclay reinforced bio-based elastomers: Synthesis and characterization Polymer 47 81068115.CrossRefGoogle Scholar