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Main Authors: Tian, Fucheng, Lu, Feixue, Sato, Katsuhiko, Li, Liangbin, Li, Bin, Gong, Jian Ping
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.11481
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author Tian, Fucheng
Lu, Feixue
Sato, Katsuhiko
Li, Liangbin
Li, Bin
Gong, Jian Ping
author_facet Tian, Fucheng
Lu, Feixue
Sato, Katsuhiko
Li, Liangbin
Li, Bin
Gong, Jian Ping
contents Double network (DN) materials exhibit anomalous strength and toughness that far exceed the sum of their constituents. While widely exploited, the fundamental physical mechanisms underlying this synergy remain elusive. Here, we show that a minimal three-dimensional model of two coupled, disordered linear-elastic networks is sufficient to capture the essential physics of DN nonlinear mechanics. The model reproduces the full suite of unique mechanical behaviors, including yielding, necking, strain hardening, and the brittle-to-ductile transition. Mechanical contrast between the hard and soft networks drives inter-network load transfer, which screens defects and suppresses stress concentrations in the hard network. By defining a stress-concentration factor, K_sc, we find that the hard-network failure strain scales universally as 1/K_sc, directly bridging microscopic defect screening to macroscopic yielding. We further show that complete defect screening triggers the shift from localized necking to delocalized damage. Furthermore, the stable necking plateau is identified as an energetic selection governed by the balance between potential energy release and irreversible dissipation. These findings reveal that a simple linear-elastic framework can account for the rich nonlinear landscape of DN materials, providing a general principle for designing next-generation tough solids.
format Preprint
id arxiv_https___arxiv_org_abs_2605_11481
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Defect screening and load transfer in minimal hard-soft double networks
Tian, Fucheng
Lu, Feixue
Sato, Katsuhiko
Li, Liangbin
Li, Bin
Gong, Jian Ping
Soft Condensed Matter
Double network (DN) materials exhibit anomalous strength and toughness that far exceed the sum of their constituents. While widely exploited, the fundamental physical mechanisms underlying this synergy remain elusive. Here, we show that a minimal three-dimensional model of two coupled, disordered linear-elastic networks is sufficient to capture the essential physics of DN nonlinear mechanics. The model reproduces the full suite of unique mechanical behaviors, including yielding, necking, strain hardening, and the brittle-to-ductile transition. Mechanical contrast between the hard and soft networks drives inter-network load transfer, which screens defects and suppresses stress concentrations in the hard network. By defining a stress-concentration factor, K_sc, we find that the hard-network failure strain scales universally as 1/K_sc, directly bridging microscopic defect screening to macroscopic yielding. We further show that complete defect screening triggers the shift from localized necking to delocalized damage. Furthermore, the stable necking plateau is identified as an energetic selection governed by the balance between potential energy release and irreversible dissipation. These findings reveal that a simple linear-elastic framework can account for the rich nonlinear landscape of DN materials, providing a general principle for designing next-generation tough solids.
title Defect screening and load transfer in minimal hard-soft double networks
topic Soft Condensed Matter
url https://arxiv.org/abs/2605.11481