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Main Authors: Noguchi, Haruka, Yukawa, Satoshi
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.11798
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author Noguchi, Haruka
Yukawa, Satoshi
author_facet Noguchi, Haruka
Yukawa, Satoshi
contents We analyze a two-dimensional spring network model comprising breakable and unbreakable springs. Computer simulations showed this system to exhibit intermittent stress drops in a larger strain regime, and these stress drops resulted in ductile-like behavior. The scaling analysis reveals that the avalanche size distribution demonstrates a cut-off, depending on its internal structure. This study also investigates the relationship between cluster growth and stress drop, and we show that the amount of stress drop increases in terms of power law, corresponding to crack growth. The crack length distribution also demonstrates a cut-off depending on its internal structure. The results show that both the cluster growth-stress drop relationship and the crack size distribution are scaled by the quantity related to the internal structure, and the relevance of the exponent that scales the cluster growth-stress drop relationship to the exponent that scales crack size distribution is verified.
format Preprint
id arxiv_https___arxiv_org_abs_2312_11798
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Fracture process of composite material in a spring network model
Noguchi, Haruka
Yukawa, Satoshi
Statistical Mechanics
We analyze a two-dimensional spring network model comprising breakable and unbreakable springs. Computer simulations showed this system to exhibit intermittent stress drops in a larger strain regime, and these stress drops resulted in ductile-like behavior. The scaling analysis reveals that the avalanche size distribution demonstrates a cut-off, depending on its internal structure. This study also investigates the relationship between cluster growth and stress drop, and we show that the amount of stress drop increases in terms of power law, corresponding to crack growth. The crack length distribution also demonstrates a cut-off depending on its internal structure. The results show that both the cluster growth-stress drop relationship and the crack size distribution are scaled by the quantity related to the internal structure, and the relevance of the exponent that scales the cluster growth-stress drop relationship to the exponent that scales crack size distribution is verified.
title Fracture process of composite material in a spring network model
topic Statistical Mechanics
url https://arxiv.org/abs/2312.11798