English

Semidilute Principle for Gels

Soft Condensed Matter 2022-12-12 v2 Materials Science Statistical Mechanics Chemical Physics

Abstract

Polymer gels such as jellies and soft contact lenses are soft solids consisting of three-dimensional polymer networks swollen with a large amount of solvent. For approximately 80 years, the swelling of polymer gels has been described using the Flory--Huggins mean-field theory. However, this theory is problematic when applied to polymer gels with large solvent contents owing to the significant fluctuations in polymer concentration. In this study, we experimentally demonstrate the superiority of the semidilute scaling law over the mean-field theory for predicting the swelling of polymer gels. Using the semidilute scaling law, we experimentally determine the universal critical exponent ν\nu of the self-avoiding walk via swelling experiments on polymer gels. The experimentally obtained value ν0.589\nu\simeq 0.589 is consistent with the previously reported value of ν0.588\nu\simeq 0.588, which was obtained by precise numerical calculations. Furthermore, we theoretically derive and experimentally demonstrate a scaling law that governs the equilibrium concentrations. This scaling law contradicts the predictions made by de Gennes' cc^{*} theorem. A major deficiency of the cc^* theorem is that the network elasticity, which depends on the as-prepared state, is neglected. These findings reveal that the semidilute scaling law is a fundamental principle for accurately predicting and controlling the equilibrium swelling of polymer gels.

Keywords

Cite

@article{arxiv.2210.15275,
  title  = {Semidilute Principle for Gels},
  author = {Naoyuki Sakumichi and Takashi Yasuda and Takamasa Sakai},
  journal= {arXiv preprint arXiv:2210.15275},
  year   = {2022}
}

Comments

13 pages, 12 figures; Appendix F and Figs.11 added to show that the semidilute principle is universal for various polymer gels

R2 v1 2026-06-28T04:37:41.915Z