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Bendability parameter for twisted ribbons to describe longitudinal wrinkling and delineate the near-threshold regime (2401.10797v3)

Published 19 Jan 2024 in cond-mat.soft

Abstract: We propose a dimensionless bendability parameter, $\epsilon{-1} = [\left(h/W\right)2 T{-1}]{-1}$ for wrinkling of thin, twisted ribbons with thickness $h$, width $W$, and tensional strain $T$. Bendability permits efficient collapse of data for wrinkle onset, wavelength, critical stress, and residual stress, demonstrating longitudinal wrinkling's primary dependence on this parameter. This new parameter also allows us to distinguish the highly bendable range ($\epsilon{-1} > 20$) from moderately bendable samples ($\epsilon{-1} \in (0,20]$). We identify scaling relations to describe longitudinal wrinkles that are valid across our entire set of simulated ribbons. When restricted to the highly bendable regime, simulations confirm theoretical near-threshold (NT) predictions for wrinkle onset and wavelength.

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References (33)
  1. E. Cerda and L. Mahadevan. Geometry and Physics of Wrinkling. Physical Review Letters, 90(7):074302, February 2003.
  2. Surface Energy as a Barrier to Creasing of Elastomer Films: An Elastic Analogy to Classical Nucleation. Physical Review Letters, 109(3):038001, July 2012. Publisher: American Physical Society.
  3. Wrinkle formations in axi-symmetrically stretched membranes. European Physical Journal E: Soft matter and biological physics, 15(2):117, 2004.
  4. Prototypical model for tensional wrinkling in thin sheets. Proceedings of the National Academy of Sciences, 108(45):18227–18232, November 2011. Publisher: Proceedings of the National Academy of Sciences.
  5. Nonperturbative model for wrinkling in highly bendable sheets. Physical Review E, 85(6):066115, June 2012.
  6. Wrinkles as the Result of Compressive Stresses in an Annular Thin Film. Communications on Pure and Applied Mathematics, 67(5):693–747, May 2014.
  7. Capillary Wrinkling of Floating Thin Polymer Films. Science, 317(5838):650–653, August 2007. Publisher: American Association for the Advancement of Science.
  8. Capillary wrinkling of elastic membranes. Soft Matter, 6(22):5778–5782, November 2010. Publisher: The Royal Society of Chemistry.
  9. Draping Films: A Wrinkle to Fold Transition. Physical Review Letters, 105(3):038303, July 2010.
  10. Capillary buckling of a floating annulus. Soft Matter, 9(46):10985–10992, November 2013. Publisher: The Royal Society of Chemistry.
  11. A drop on a floating sheet: boundary conditions, topography and formation of wrinkles. Soft Matter, 9(34):8289–8296, August 2013. Publisher: The Royal Society of Chemistry.
  12. Indentation of Ultrathin Elastic Films and the Emergence of Asymptotic Isometry. Physical Review Letters, 114(1):014301, January 2015. Publisher: American Physical Society.
  13. Indentation of a floating elastic sheet: geometry versus applied tension. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 473(2206):20170335, October 2017. Publisher: Royal Society.
  14. Universal collapse of stress and wrinkle-to-scar transition in spherically confined crystalline sheets. Proceedings of the National Academy of Sciences, 110(32):12893–12898, August 2013. Publisher: Proceedings of the National Academy of Sciences.
  15. Sheet on a deformable sphere: Wrinkle patterns suppress curvature-induced delamination. Physical Review E, 91(1):012407, January 2015.
  16. Geometrically incompatible confinement of solids. Proceedings of the National Academy of Sciences, 116(5):1483–1488, January 2019. Publisher: Proceedings of the National Academy of Sciences.
  17. Wrinkling in the deflation of elastic bubbles. The European Physical Journal E, 36(3):22, March 2013.
  18. Albert Edward Green. The elastic stability of a thin twisted strip—II. Proceedings of the Royal Society of London. Series A - Mathematical and Physical Sciences, 161(905):197–220, July 1937. Publisher: Royal Society.
  19. Stability of twisted orthotropic plates. International Journal of Mechanical Sciences, 28(6):371–379, January 1986.
  20. An asymptotic description of the elastic instability of twisted thin elastic plates. Acta Mechanica, 200(1-2):59–68, September 2008.
  21. Roadmap to the Morphological Instabilities of a Stretched Twisted Ribbon, pages 137–189. Springer Netherlands, Dordrecht, 2016.
  22. From Cylindrical to Stretching Ridges and Wrinkles in Twisted Ribbons. Physical Review Letters, 117(10):104301, September 2016. Publisher: American Physical Society.
  23. Helicoids, Wrinkles, and Loops in Twisted Ribbons. Physical Review Letters, 111(17):174302, October 2013.
  24. Computational model of twisted elastic ribbons. Physical Review E, 108:015003, 2023.
  25. Julien Chopin and Romildo T. D. Filho. Extreme contractility and torsional compliance of soft ribbons under high twist. Phys. Rev. E, 99:043002, Apr 2019.
  26. Curvature-induced stiffness and the spatial variation of wavelength in wrinkled sheets. Proceedings of the National Academy of Sciences, 113(5):1144–1149, February 2016. Publisher: Proceedings of the National Academy of Sciences.
  27. Defects in flexible membranes with crystalline order. Physical Review A, 38(2):1005–1018, July 1988.
  28. Allen Van Gelder. Approximate simulation of elastic membranes by triangulated spring meshes. Journal of Graphics Tools, 3(2):21–41, 1998.
  29. Identification of Spring Parameters for Deformable Object Simulation. IEEE Transactions on Visualization and Computer Graphics, 13(5):1081–1094, September 2007.
  30. Discrete shells. In Proceedings of the 2003 ACM SIGGRAPH/Eurographics symposium on Computer animation, SCA ’03, pages 62–67, Goslar, DEU, July 2003. Eurographics Association.
  31. Discrete bending forces and their Jacobians. Graphical Models, 75(6):362–370, November 2013.
  32. Simulation of crumpled sheets via alternating quasistatic and dynamic representations. Journal of Computational Physics, 471:111607, 2022.
  33. Zhanlong Qiu. Morphology of Thin Sheets in the Lame Setup and Beyond. PhD thesis, University of Massachusetts Amherst, March 2017.

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