Papers
Topics
Authors
Recent
Assistant
AI Research Assistant
Well-researched responses based on relevant abstracts and paper content.
Custom Instructions Pro
Preferences or requirements that you'd like Emergent Mind to consider when generating responses.
Gemini 2.5 Flash
Gemini 2.5 Flash 134 tok/s
Gemini 2.5 Pro 41 tok/s Pro
GPT-5 Medium 28 tok/s Pro
GPT-5 High 39 tok/s Pro
GPT-4o 101 tok/s Pro
Kimi K2 191 tok/s Pro
GPT OSS 120B 428 tok/s Pro
Claude Sonnet 4.5 37 tok/s Pro
2000 character limit reached

Modeling Shortest Paths in Polymeric Networks using Spatial Branching Processes (2310.18551v2)

Published 28 Oct 2023 in math-ph, math.MP, and math.PR

Abstract: Recent studies have established a connection between the macroscopic mechanical response of polymeric materials and the statistics of the shortest path (SP) length between distant nodes in the polymer network. Since these statistics can be costly to compute and difficult to study theoretically, we introduce a branching random walk (BRW) model to describe the SP statistics from the coarse-grained molecular dynamics (CGMD) simulations of polymer networks. We postulate that the first passage time (FPT) of the BRW to a given termination site can be used to approximate the statistics of the SP between distant nodes in the polymer network. We develop a theoretical framework for studying the FPT of spatial branching processes and obtain an analytical expression for estimating the FPT distribution as a function of the cross-link density. We demonstrate by extensive numerical calculations that the distribution of the FPT of the BRW model agrees well with the SP distribution from the CGMD simulations. The theoretical estimate and the corresponding numerical implementations of BRW provide an efficient way of approximating the SP distribution in a polymer network. Our results have the physical meaning that by accounting for the realistic topology of polymer networks, extensive bond-breaking is expected to occur at a much smaller stretch than that expected from idealized models assuming periodic network structures. Our work presents the first analysis of polymer networks as a BRW and sets the framework for developing a generalizable spatial branching model for studying the macroscopic evolution of polymeric systems.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (60)
  1. Nanoindentation of polydimethylsiloxane elastomers: Effect of crosslinking, work of adhesion, and fluid environment on elastic modulus. Journal of Materials Research, 20(10):2820–2830, 2005.
  2. B Erman and JE Mark. Rubber-like elasticity. Annual Review of Physical Chemistry, 40(1):351–374, 1989.
  3. Millard F Beatty. Topics in finite elasticity: Hyperelasticity of rubber, elastomers, and biological tissues—with examples. Applied Mechanics Reviews, 40:1699–1734, 1987.
  4. Finite element modelling of cure-dependent mechanical properties by model-free kinetic analysis using a cohesive zone approach. The Journal of Adhesion, 92(7-9):572–585, 2016.
  5. 3d multiscale modeling to predict the elastic modulus of polymer/nanoclay composites considering realistic interphase property. Composite Interfaces, 23(7):641–661, 2016.
  6. A three-dimensional constitutive model for the large stretch behavior of rubber elastic materials. Journal of the Mechanics and Physics of Solids, 41(2):389–412, 1993.
  7. Dynamics of entangled linear polymer melts: A molecular-dynamics simulation. The Journal of Chemical Physics, 92(8):5057–5086, 1990.
  8. Coarse-grained molecular-dynamics simulations of nanoparticle diffusion in polymer nanocomposites. Polymer, 145:80–87, 2018.
  9. Coarse-grained molecular dynamics simulation of polymers: Structures and dynamics. Wiley Interdisciplinary Reviews: Computational Molecular Science, 13(6):e1683, 2023.
  10. Molecular dynamics simulations of ion-containing polymers using generic coarse-grained models. Macromolecules, 54(5):2031–2052, 2021.
  11. A review of advancements in coarse-grained molecular dynamics simulations. Molecular Simulation, 47(10-11):786–803, 2021.
  12. Permanent set of cross-linking networks: Comparison of theory with molecular dynamics simulations. Macromolecules, 39(16):5521–5530, 2006.
  13. Toughening elastomers with sacrificial bonds and watching them break. Science, 344(6180):186–189, 2014.
  14. Topological origin of strain induced damage of multi-network elastomers by bond breaking. Extreme Mechanics Letters, 40:100883, 2020.
  15. PJ Flory. Elasticity of polymer networks cross-linked in states of strain. Transactions of the Faraday Society, 56:722–743, 1960.
  16. Disorder effects on the strain response of model polymer networks. Polymer, 46(12):4283–4295, 2005.
  17. Length of subchains and chain ends in cross-linked polymer networks. Macromolecules, 36(12):4646–4658, 2003.
  18. Langevin dynamics simulation of chain crosslinking into polymer networks. Macromolecular theory and simulations, 21(4):250–265, 2012.
  19. Minima in branching random walks. Annals of Probability, 37(3):1044–1079, 2009.
  20. Elie Aïdékon. Convergence in law of the minimum of a branching random walk. Annals of Probability, 41(3A):1362–1426, 2013.
  21. Convergence in law of the maximum of nonlattice branching random walk. Annales de l’Institut Henri Poincaré - Probabilités et Statistiques, 52(4):1897–1924, 2016.
  22. Thomas Madaule. Convergence in law for the branching random walk seen from its tip. Journal of Theoretical Probability, 30:27–63, 2017.
  23. Maury D Bramson. Maximal displacement of branching Brownian motion. Communications on Pure and Applied Mathematics, 31(5):531–581, 1978.
  24. A conditional limit theorem for the frontier of a branching brownian motion. The Annals of Probability, pages 1052–1061, 1987.
  25. Matthew I Roberts. A simple path to asymptotics for the frontier of a branching Brownian motion. Annals of Probability, 41(5):3518–3541, 2013.
  26. Branching Brownian motion seen from its tip. Probability Theory and Related Fields, 157:405–451, 2013.
  27. The extremal process of branching Brownian motion. Probability Theory and Related Fields, 157(3-4):535–574, 2013.
  28. Bastien Mallein. Maximal displacement in the d𝑑ditalic_d-dimensional branching Brownian motion. Electronic Communications in Probability, 20:1–12, 2015.
  29. The extremal point process of branching Brownian motion in ℝdsuperscriptℝ𝑑\mathbb{R}^{d}blackboard_R start_POSTSUPERSCRIPT italic_d end_POSTSUPERSCRIPT. ArXiv preprint arXiv:2112.08407. To appear, Ann. Probab., 2021.
  30. The maximum of branching Brownian motion in ℝdsuperscriptℝ𝑑\mathbb{R}^{d}blackboard_R start_POSTSUPERSCRIPT italic_d end_POSTSUPERSCRIPT. The Annals of Applied Probability, 33(2):1515–1568, 2023.
  31. The maximal displacement of radially symmetric branching random walk in ℝdsuperscriptℝ𝑑\mathbb{R}^{d}blackboard_R start_POSTSUPERSCRIPT italic_d end_POSTSUPERSCRIPT. ArXiv preprint arXiv:2309.14738, 2023.
  32. LAMMPS - a flexible simulation tool for particle-based materials modeling at the atomic, meso, and continuum scales. Comp. Phys. Comm., 271:108171, 2022.
  33. Fast protocol for equilibration of entangled and branched polymer chains. Chemical Physics Letters, 523:139–143, 2012.
  34. Molecular dynamics simulations of polymer welding: Strength from interfacial entanglements. Physical Review Letters, 110(9):098301, 2013.
  35. Edsger W Dijkstra. A note on two problems in connexion with graphs. Numerische Mathematik, 1:269–271, 1959.
  36. The Theory of Polymer Dynamics, volume 73. Oxford University Press, 1988.
  37. William W Graessley. Polymeric Liquids & Networks: Structure and Properties. Garland Science, 2003.
  38. Multivalent assembly of flexible polymer chains into supramolecular nanofibers. Journal of the American Chemical Society, 142(39):16814–16824, 2020.
  39. Polymer Physics, volume 23. Oxford University Press New York, 2003.
  40. Equilibration of long chain polymer melts in computer simulations. The Journal of Chemical Physics, 119(24):12718–12728, 2003.
  41. Enhancement of inhomogeneities in gels upon swelling and stretching. In Makromolekulare Chemie. Macromolecular Symposia, volume 40, pages 81–99. Wiley Online Library, 1990a.
  42. Scattering by deformed swollen gels: butterfly isointensity patterns. Macromolecules, 23(6):1821–1825, 1990b.
  43. Thomas A Vilgis. Rubber elasticity and inhomogeneities in crosslink density. Macromolecules, 25(1):399–403, 1992.
  44. P.-G. de Gennes. Scaling Concepts in Polymer Physics. Cornell University Press, 1979.
  45. Michel Talagrand. A new look at independence. Annals of Probability, 24(1):1–34, 1996.
  46. SV Panyukov. Microscopic theory of anisotropic scattering by deformed polymer networks. Soviet Journal of Experimental and Theoretical Physics, 75(2):347, 1992.
  47. Solid elasticity and liquid-like behaviour in randomly crosslinked polymer networks. Europhysics Letters, 28(2):149, 1994.
  48. Effect of finite extensibility on the viscoelastic properties of a styrene–butadiene rubber vulcanizate in simple tensile deformations up to rupture. Journal of Polymer Science Part A-2: Polymer Physics, 7(4):635–658, 1969.
  49. Thor L Smith. Modulus of tightly crosslinked polymers related to concentration and length of chains. In Journal of Polymer Science: Polymer Symposia, volume 46, pages 97–114. Wiley Online Library, 1974.
  50. Large Deviations Techniques and Applications. Springer, 1998.
  51. On the first passage times of branching random walks in ℝdsuperscriptℝ𝑑\mathbb{R}^{d}blackboard_R start_POSTSUPERSCRIPT italic_d end_POSTSUPERSCRIPT. In preparation, 2023+.
  52. Paul G Higgs and RC Ball. Polydisperse polymer networks: elasticity, orientational properties, and small angle neutron scattering. Journal de Physique, 49(10):1785–1811, 1988.
  53. Ronald Aylmer Fisher. The wave of advance of advantageous genes. Annals of Eugenics, 7(4):355–369, 1937.
  54. Étude de l’équation de la diffusion avec croissance de la quantité de matière et son application à un problème biologigue. Moscow Univ. Bull. Ser. Internat. Sect. A, 1:1, 1937.
  55. Henry P McKean. Application of Brownian motion to the equation of Kolmogorov-Petrovskii-Piskunov. Communications on Pure and Applied Mathematics, 28(3):323–331, 1975.
  56. Jürgen Gärtner. Location of wave fronts for the multi-dimensional K-P-P equation and Brownian first exit densities. Mathematische Nachrichten, 105(1):317–351, 1982.
  57. Arnaud Ducrot. On the large time behaviour of the multi-dimensional Fisher–KPP equation with compactly supported initial data. Nonlinearity, 28(4):1043, 2015.
  58. Sharp large time behaviour in N𝑁Nitalic_N-dimensional Fisher-KPP equations. Discrete and Continuous Dynamical Systems A, 39:7265–7290, 2019.
  59. Mehmet Öz. On the density of branching Brownian motion. Hacettepe Journal of Mathematics & Statistics, 52(1):229–247, 2023.
  60. Asymptotic behavior and stability in linear impulsive delay differential equations with periodic coefficients. Mathematics, 8(10):1802, 2020.
Citations (3)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
Dice Question Streamline Icon: https://streamlinehq.com

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now
Lightbulb Streamline Icon: https://streamlinehq.com

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now
List To Do Tasks Checklist Streamline Icon: https://streamlinehq.com

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up
X Twitter Logo Streamline Icon: https://streamlinehq.com

Tweets

This paper has been mentioned in 1 tweet and received 1 like.

Upgrade to Pro to view all of the tweets about this paper:

Start a free 7-day Pro trial