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5 - Thermally stable polyimide/4,4′-bis(4-aminophenoxy)phenylsulfone-modified clay nanocomposites

from Part I - Thermal stability

Published online by Cambridge University Press:  05 August 2011

Joshua U. Otaigbe
Affiliation:
aInstitute of Macromolecular Compounds, Russian Academy of Sciences, Russia bSchool of Polymers and High Performance Materials, The University of Southern Mississippi, USA
Vikas Mittal
Affiliation:
The Petroleum Institute, Abu Dhabi
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Summary

Polyimide/clay nanocomposites

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Publisher: Cambridge University Press
Print publication year: 2011

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References

Ray, S.Okamoto, M.Polymer/layered silicate nanocomposites: A review from preparation to processingProgress in Polymer Science 28 2003 1539Google Scholar
Giannelis, E. P.Polymer layered silicate nanocompositesAdvanced Materials 8 1996 29CrossRefGoogle Scholar
Giannelis, E. P.Krishnamoorti, R.Manias, E.Polymer-silicate nanocomposites: Model systems for confined polymers and polymer brushesAdvanced Polymer Science 138 1999 107CrossRefGoogle Scholar
LeBaron, P. C.Wang, Z.Pinnavaia, T. J.Polymer-layered silicate nanocomposites: An overviewApplied Clay Science 15 1999 11CrossRefGoogle Scholar
Vaia, R. A.Price, G.Ruth, P. N.Nguyen, H. T.Lichtenhan, J.Polymer/layered silicate nanocomposites as high performance ablative materialsApplied Clay Science 15 1999 67CrossRefGoogle Scholar
Biswas, M.Ray, S. S.Recent progress in synthesis and evaluation of polymer–montmorillonite nanocompositesAdvanced Polymer Science 155 2001 167CrossRefGoogle Scholar
Xu, R.Manias, E.Snyder, A. J.Runt, J.New biomedical poly(urethane urea)–layered silicate nanocompositesMacromolecules 34 2001 337CrossRefGoogle Scholar
Bharadwaj, R. K.Modeling the barrier properties of polymer layered silicate nanocompositesMacromolecules 34 2001 1989CrossRefGoogle Scholar
Kojima, Y.Usuki, A.Kawasumi, M.Fukushima, Y.Okada, A.Kurauch, T.Kamigaito, O.Synthesis of nylon 6–clay hybridJournal of Materials Research 8 1993 1179CrossRefGoogle Scholar
Bessonov, M. I.Koton, M. M.Kudryavtsev, V. V.Laius, L. A.Polyimides – Thermally Stable PolymersNew YorkPlenum 1987Google Scholar
Wilson, D.Stengenberger, H. D.Hergenrother, P. M.PolyimidesNew YorkChapman & Hall 1990CrossRefGoogle Scholar
Ghose, M. K.Mittal, K. L.Polyimides – Fundamentals and ApplicationsNew YorkDekker 1996Google Scholar
Yano, K.Usuki, A.Okada, A.Kurauchi, T.Kamigaito, O.Synthesis and properties of polyimide clay hybridJournal of Polymer Science, Part A: Polymer Chemistry 31 1993 2493CrossRefGoogle Scholar
Yang, Y.Zhu, Z.-K.Yin, J.Wang, X.-Y.Qi, Z.-E.Preparation and properties of hybrids of organo-soluble polyimide and montmorillonite with various chemical surface modificationPolymer 40 1999 4407CrossRefGoogle Scholar
Delozier, D. M.Orwoll, R. A.Cahoon, J. F.Johnston, N. J.Smith, Jr J. G.Connell, J. W.Preparation and characterization of polyimide/organoclay nanocompositePolymer 43 2002 813CrossRefGoogle Scholar
Tyan, H.-L.Liu, Y.-C.Wei, K.-H.Thermally and mechanically enhanced clay/polyimide nanocomposite via reactive organoclayChemistry of Materials 11 1999 1942CrossRefGoogle Scholar
Tyan, H.-L.Liu, C.-M.Wei, K.-H.Effect of reactivity of organics-modified montmorillonite on the thermal and mechanical properties of montmorillonite/polyimide nanocompositesChemistry of Materials 13 2001 222CrossRefGoogle Scholar
Tyan, H.-L.Wei, K.-H.Hsieh, T.-E.Mechanical properties of clay–polyimide (BTDA–ODA) nanocomposites via ODA-modified organoclayJournal of Polymer Science, Part B: Polymer Physics 38 2000 28733.0.CO;2-T>CrossRefGoogle Scholar
Vora, R. H.Pallathadka, P. K.Goh, S. H.Chung, T. S.Lim, Y. X.Bang, T. K.Preparation and characterization of 4,4-bis(4-aminophenoxy)diphenyl sulfone based fluoropoly(ether-imide)/organo-modified clay nanocompositesMacromolecular Materials and Engineering 288 2003 337CrossRefGoogle Scholar
Liang, Z.-M.Yin, J.Xu, H.-J.Polyimide/montmorillonite nanocomposites based on thermally stable, rigid-rod aromatic amine modifiersPolymer 44 2003 1391CrossRefGoogle Scholar
Liang, Z.-M.Yin, J.Poly(etherimide)/montmorillonite nanocomposites prepared by melt intercalationJournal of Applied Polymer Science 90 2003 1857CrossRefGoogle Scholar
Campbell, S.Scheiman, D.Orientation of aromatic ion exchange diamines and the effect on melt viscosity and thermal stability of PMR-15/silicate nanocompositesHigh Performance Polymers 14 2002 17CrossRefGoogle Scholar
Yudin, V. E.Divoux, G. M.Otaigbe, J. U.Svetlichnyi, V. M.Synthesis and rheological properties of oligoimide/montmorillonite nanocompositesPolymer 46 2005 10CrossRefGoogle Scholar
Zhong, Y.Wang, S.-Q.Exfoliation and yield behavior in nanodispersions of organically modified montmorillonite clayJournal of Rheology 47 2003 483CrossRefGoogle Scholar
Laribi, S.Fleureau, J.-M.Grossiord, J.-L.Kbir-Ariguib, N.Effect of pH on the rheological behaviour of pure and interstratified smectite claysClays and Clay Minerals 54 2006 29CrossRefGoogle Scholar
Tarchitzky, J.Chen, Y.Rheology of humic substances/ Na- and Ca-montmorillonite suspensionsSoil Science Society of America Journal 66 2002 406CrossRefGoogle Scholar
Cadene, A.Durand-Vidal, S.Turqa, P.Brendle, J.Study of individual Na-montmorillonite particles size, morphology, and apparent chargeJournal of Colloid and Interface Science 285 2005 719CrossRefGoogle ScholarPubMed
Falini, G.Foresti, E.Lesci, G.Roveri, N.Structural and morphological characterization of synthetic chrysotile single crystalsChemical Communication 2002 1512CrossRefGoogle ScholarPubMed
Zhang, Y.Lu, S.Li, Y.Dang, Z.Xin, J.Fu, S.Li, G.Guo, R.Li, L.Novel silica tube/polyimide composite films with variable low dielectric constantAdvanced Materials 17 2005 1056CrossRefGoogle Scholar
Korytkova, E.Maslov, A.Pivovarova, L.Drozdova, I.Gusarov, V.Formation of Mg3Si2O5(OH)4 nanotubes under hydrothermal conditionsGlass Physics and Chemistry 30 2004 51CrossRefGoogle Scholar
Pozhidaeva, O.Korytkova, E.Romanov, D.Gusarov, V.Formation of ZrO2 nanocrystals in hydrothermal media of various chemical compositionsRussian Journal of General Chemistry 72 2002 849CrossRefGoogle Scholar
Yudin, V.Otaigbe, J.Gladchenko, S.Olson, B.Nazarenko, S.Korytkova, E.Gusarov, V.New polyimide nanocomposites based on silicate type nanotubes: Dispersion, processing and propertiesPolymer 48 2007 1306CrossRefGoogle Scholar
Gelest, IncSilane Coupling Agents: Connecting across BoundariesArkles, B.Morrisville, PAGelest 1998 88Google Scholar
Potschke, P.Fornes, T. D.Paul, D. R.Rheological behaviour of multiwalled carbon nanotube/polycarbonate compositesPolymer 43 2002 3247CrossRefGoogle Scholar
Wu, G.Lin, J.Zheng, Q.Zhang, M.Correlation between percolation behavior of electricity and viscoelasticity for graphite filled high density polyethylenePolymer 47 2006 2442CrossRefGoogle Scholar
Liu, C.Zhang, J.He, J.Hu, G.Gelation in carbon nanotube/polymer compositesPolymer 44 2003 7529CrossRefGoogle Scholar
Garboczi, E.Snyder, K.Douglas, J.Thorpe, M.Geometrical percolation threshold of overlapping ellipsoidsPhysical Review E 52 1995 819CrossRefGoogle ScholarPubMed
Zeng, Q.Yu, A.Lu, G.Paul, D.Clay-based polymer nanocomposites: Research and commercial developmentJournal of Nanoscience and Nanotechnology 5 2005 1574CrossRefGoogle ScholarPubMed
Paquiena, J.-N.Galya, J.Gerarda, J.-F.Pouchelon, A.Rheological studies of fumed silica–polydimethylsiloxane suspensionsColloids and Surfaces A: Physicochemical and Engineering Aspects 260 2005 165CrossRefGoogle Scholar
Thomas, D. J.Transport characteristics of suspension. VIII. A note on the viscosity of Newtonian suspensions of uniform spherical particlesJournal of Colloid and Interface Science 20 1965 267CrossRefGoogle Scholar
Nielsen, L.Mechanical Properties of Polymers and CompositesNew YorkDekker 1994Google Scholar
Barnes, H.Thixotropy – A reviewJournal of Non-Newtonian Fluid Mechanics 70 1997 1CrossRefGoogle Scholar
Svetlichnyi, V. M.Zhukova, T. I.Kudriavtsev, V. V.Yudin, V. E.Gubanova, G. N.Leksovskii, A. M.Aromatic polyetherimides as promising fusible film bindersPolymer Engineering and Science 35 1995 1321CrossRefGoogle Scholar
Nesterov, V. V.Kudryavtsev, V. V.Svetlichnyi, V. M.Gazdina, N. V.Belnikevich, N. G.Kurenbin, O. I.Zhukova, T. I.Study of soluble poly(amic acid)s and poly(ester imide)s by methods of exclusion liquid chromatographyPolymer Science, Series A 39 1997 953Google Scholar
Olson, B. G.Decker, J. J.Nazarenko, S. I.Yudin, V. E.Otaigbe, J. U.Korytkova, E. N.Gusarov, V. V.Aggregation of synthetic chrysotile nanotubes in the bulk and in solution probed by nitrogen adsorption and viscosity measurementsJournal of Physical Chemistry: Part C 112 2008 12Google Scholar
Kurose, T.Yudin, V. E.Otaigbe, J. U.Svetlichnyi, V. M.Polymer 48 2007 7130CrossRef
Yudin, V. E.Otaigbe, J. U.Svetlichnyi, V. M.Korytkova, E. N.Almjasheva, O. V.Effects of nanofiller morphology and aspect ratio on the rheo-mechanical properties of polyimide nanocompositeseXPRESS Polymer Letters 2 2008 485CrossRefGoogle Scholar

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