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All issues Volume 644 (2025) E3S Web Conf., 644 (2025) 02019 References
Open Access
Issue
E3S Web Conf.
Volume 644, 2025
EUROGEO 8 - 8th European Conference on Geosynthetics
Article Number 02019
Number of page(s) 10
Section Testing and Quality
DOI https://doi.org/10.1051/e3sconf/202564402019
Published online 01 September 2025
  1. D. Cazzuffi, J. Giroud, A. Scuero, G. Vaschetti, Geosynthetic barriers systems for dams. 9th International Conference on Geosynthetics Geosynthetics: Advanced Solutions for a Challenging World, ICG 2010. 115–164 (2010) [Google Scholar]
  2. Y. Zhang, Z. Yan, The general theory of viscoelasticity under non-constant temperature states. Chinese Journal of Theoretical and Applied Mechanics. 25, 685–696 (1993) [Google Scholar]
  3. A. M. Noval, Estudio del comportamiento de tres geomembranas de EPDM, PVC-P y PEAD a lo largo del tiempo, Tesis doctoral, Universidad Carlos III, Madrid, Spain (2015) [Google Scholar]
  4. X. Zhang, Z. Ma, Y. Wu, J. Liu, Response of Mechanical Properties of Polyvinyl Chloride Geomembrane to Ambient Temperature in Axial Tension. Applied Sciences. 11, 10864 (2021) [Google Scholar]
  5. Y. G. Hsuan, H. F. Schroeder, K. Rowe, W. Müller, J. Greenwood, D. Cazzuffi, R.M. Koerner, Long-term performace and lifetime prediction of geosynthetics. EuroGeo4. 1–40 (2008) [Google Scholar]
  6. J. P. Giroud, Evaluation of PVC Geomembrane Shrinkage Due to Plasticizer Loss. Geosynthetics International. 2, 1099–1113 (1995) [Google Scholar]
  7. R. K. Rowe, S. Rimal, H. Sangam, Ageing of HDPE geomembrane exposed to air, water and leachate at different temperatures. Geotextiles and Geomembranes. 27, 137–151 (2009) [CrossRef] [Google Scholar]
  8. M. V. Akpinar, C. H. Benson, Effect of temperature on shear strength of two geomembrane–geotextile interfaces. Geotextiles and Geomembranes. 23, 443–453, Oct. 2005 [Google Scholar]
  9. A. Krairi, I. Doghri, A thermodynamically-based constitutive model for thermoplastic polymers coupling viscoelasticity, viscoplasticity and ductile damage. International Journal of Plasticity. 60, 163–181 (2014) [Google Scholar]
  10. R. N. Haward, Heating effects in the deformation of thermoplastics. Thermochimica Acta. 247, 87–109 (1994) [Google Scholar]
  11. W. M. Barentsen, D. Heikens, Mechanical properties of polystyrene/low density polyethylene blends. Polymer. 14, 579–583 (1973) [Google Scholar]
  12. B. Bax, J. Müssig, Impact and tensile properties of PLA/Cordenka and PLA/flax composites. Composites Science and Technology. 68, 1601–1607 (2008) [Google Scholar]
  13. M. A. Kennedy, A. J. Peacock, L. Mandelkern, Tensile Properties of Crystalline Polymers: Linear Polyethylene. Macromolecules. 27, 5297–5310 (1994) [Google Scholar]
  14. L. Mullins, Effect of Stretching on the Properties of Rubber. Rubber Chemistry and Technology. 21, 281–300 (1948) [Google Scholar]
  15. L. E. Nielsen, Cross-Linking–Effect on Physical Properties of Polymers. Journal of Macromolecular Science. 3, 69–103 (1969) [Google Scholar]
  16. S. Jabbari-Farouji, J. Rottler, O. Lame, A. Makke, M. Perez, J.-L. Barrat, Plastic Deformation Mechanisms of Semicrystalline and Amorphous Polymers. ACS Macro Lett. 4, 147–150 (2015) [Google Scholar]
  17. F. Detrez, S. Cantournet, R. Seguela, Plasticity/damage coupling in semi-crystalline polymers prior to yielding: Micromechanisms and damage law identification. Polymer. 52, 1998–2008 (2011) [Google Scholar]
  18. F. Zaïri, M. Naït-Abdelaziz, J. M. Gloaguen, J. M. Lefebvre, A physically-based constitutive model for anisotropic damage in rubber-toughened glassy polymers during finite deformation. International Journal of Plasticity. 27, 25–51 (2011) [Google Scholar]
  19. G. Ayoub, F. Zaïri, M. Naït-Abdelaziz, J. M. Gloaguen, Modeling the low-cycle fatigue behavior of visco-hyperelastic elastomeric materials using a new network alteration theory: Application to styrene-butadiene rubber. Journal of the Mechanics and Physics of Solids. 59, 473–495 (2011) [Google Scholar]
  20. V.-D. Nguyen, F. Lani, T. Pardoen, X. P. Morelle, L. Noels, A large strain hyperelastic viscoelastic-viscoplastic-damage constitutive model based on a multi-mechanism nonlocal damage continuum for amorphous glassy polymers. International Journal of Solids and Structures. 96, 192–216 (2016) [Google Scholar]
  21. R. Balieu, F. Lauro, B. Bennani, R. Delille, T. Matsumoto, E. Mottola, A fully coupled elastoviscoplastic damage model at finite strains for mineral filled semi-crystalline polymer. International Journal of Plasticity. 51, 241–270 (2013) [Google Scholar]
  22. M. C. Boyce, E. M. Arruda, R. Jayachandran, The large strain compression, tension, and simple shear of polycarbonate. Polymer Engineering & Science. 34, 716–725 (1994) [Google Scholar]
  23. K. Chen, G. Kang, F. Lu, J. Chen, H. Jiang, Effect of relative humidity on uniaxial cyclic softening/hardening and intrinsic heat generation of polyamide-6 polymer. Polymer Testing. 56, 19–28 (2016) [Google Scholar]
  24. W. Chen, F. Lu, M. Cheng, Tension and compression tests of two polymers under quasistatic and dynamic loading. Polymer Testing. 21, 113–121 (2002) [Google Scholar]
  25. P. J. Hine, R. A. Duckett, A. S. Kaddour, M. J. Hinton, G. M. Wells, The effect of hydrostatic pressure on the mechanical properties of glass fibre/epoxy unidirectional composites. Composites Part A: Applied Science and Manufacturing. 36, 279–289 (2005) [Google Scholar]
  26. V. Srivastava, S. A. Chester, N. M. Ames, L. Anand, A thermo-mechanically-coupled large-deformation theory for amorphous polymers in a temperature range which spans their glass transition. International Journal of Plasticity. 26, 1138–1182 (2010) [Google Scholar]
  27. A. Maurel-Pantel, E. Baquet, J. Bikard, J. L. Bouvard, N. Billon, A thermo-mechanical large deformation constitutive model for polymers based on material network description: Application to a semi-crystalline polyamide 66. International Journal of Plasticity. 67, 102–126 (2015) [Google Scholar]
  28. C. Ovalle Rodas, F. Zaïri, M. Naït-Abdelaziz, A finite strain thermo-viscoelastic constitutive model to describe the self-heating in elastomeric materials during low-cycle fatigue. Journal of the Mechanics and Physics of Solids. 64, 396–410 (2014) [Google Scholar]
  29. B. Jordan, M. B. Gorji, D. Mohr, Neural network model describing the temperatureand rate-dependent stress-strain response of polypropylene. International Journal of Plasticity. 135, 102811 (2020) [Google Scholar]
  30. P. Lin, J. Liu, S.-Q. Wang, Delineating nature of stress responses during ductile uniaxial extension of polycarbonate glass. Polymer. 89, 143–153 (2016) [Google Scholar]
  31. F. Shen, G. Kang, Y. C. Lam, Y. Liu, K. Zhou, Thermo-elastic-viscoplastic-damage model for self-heating and mechanical behavior of thermoplastic polymers. International Journal of Plasticity. 121, 227–243 (2019) [Google Scholar]

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