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Shear-induced phase transition and critical exponents in three-dimensional fiber networks

Sadjad Arzash, Jordan L. Shivers, Fred C. MacKintosh

2021Physical review. E14 citationsDOIOpen Access PDF

Abstract

When subject to applied strain, fiber networks exhibit nonlinear elastic stiffening. Recent theory and experiments have shown that this phenomenon is controlled by an underlying mechanical phase transition that is critical in nature. Growing simulation evidence points to non-mean-field behavior for this transition and a hyperscaling relation has been proposed to relate the corresponding critical exponents. Here, we report simulations on two distinct network structures in three dimensions. By performing a finite-size scaling analysis, we test hyperscaling and identify various critical exponents. From the apparent validity of hyperscaling, as well as the non-mean-field exponents we observe, our results suggest that the upper critical dimension for the strain-controlled phase transition is above three, in contrast to the jamming transition that represents another athermal, mechanical phase transition.

Topics & Concepts

Critical exponentPhase transitionCritical dimensionScalingJammingStatistical physicsCritical phenomenaNonlinear systemDimension (graph theory)MathematicsCritical point (mathematics)Phase (matter)PhysicsCondensed matter physicsFiberPercolation critical exponentsScaling lawWidom scalingMathematical analysisStress (linguistics)Transition (genetics)Critical frequencyComplex systemCharacterization (materials science)Series (stratigraphy)Transition pointTheoretical and Computational PhysicsMaterial Dynamics and PropertiesThermal properties of materials