Saved in:
Bibliographic Details
Main Author: Masubuchi, Yuichi
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.00278
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913391019294720
author Masubuchi, Yuichi
author_facet Masubuchi, Yuichi
contents Despite numerous studies, the relationship between network structure and fracture remains unclear. In this study, the fracture properties of end-linking networks were compared with those of loop-free analogs made from star prepolymers by performing phantom chain simulations. The networks were created from equilibrated sols of stoichiometric mixtures of linear prepolymers and f-functional linkers through end-linking reactions using Brownian dynamics schemes. The examined networks, with various f values (between 3 and 8) and strand-connection rates (ϕ_s), were evaluated in terms of the primary loop fraction and the cycle rank ξ. These structural characteristics were consistent with mean-field theories that assume independent reactions. Energy minimization and uniaxial stretch were applied to the networks until they broke without Brownian motion. The fracture characteristics, including strain (ε_b), stress (σ_b), and work for fracture (W_b), were obtained from stress-strain curves. The end-linking networks exhibited larger ε_b and smaller σ_b and W_b than those for star networks due to primary loops, at the same set of f and ϕ_s. However, ε_b, σ_b/ν_br and W_b/ν_br (with ν_br being the branch point density) lie on the same master curves as those for star networks if they are plotted against ξ. This result implies that the fracture of end-linking networks is essentially the same as that for star analogs, and the effects of primary loops are embedded in ξ.
format Preprint
id arxiv_https___arxiv_org_abs_2402_00278
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Phantom Chain Simulations for Fracture of End-linking Networks
Masubuchi, Yuichi
Soft Condensed Matter
Despite numerous studies, the relationship between network structure and fracture remains unclear. In this study, the fracture properties of end-linking networks were compared with those of loop-free analogs made from star prepolymers by performing phantom chain simulations. The networks were created from equilibrated sols of stoichiometric mixtures of linear prepolymers and f-functional linkers through end-linking reactions using Brownian dynamics schemes. The examined networks, with various f values (between 3 and 8) and strand-connection rates (ϕ_s), were evaluated in terms of the primary loop fraction and the cycle rank ξ. These structural characteristics were consistent with mean-field theories that assume independent reactions. Energy minimization and uniaxial stretch were applied to the networks until they broke without Brownian motion. The fracture characteristics, including strain (ε_b), stress (σ_b), and work for fracture (W_b), were obtained from stress-strain curves. The end-linking networks exhibited larger ε_b and smaller σ_b and W_b than those for star networks due to primary loops, at the same set of f and ϕ_s. However, ε_b, σ_b/ν_br and W_b/ν_br (with ν_br being the branch point density) lie on the same master curves as those for star networks if they are plotted against ξ. This result implies that the fracture of end-linking networks is essentially the same as that for star analogs, and the effects of primary loops are embedded in ξ.
title Phantom Chain Simulations for Fracture of End-linking Networks
topic Soft Condensed Matter
url https://arxiv.org/abs/2402.00278