Carmen L. Lee, Ephraim Bililign, Emilien Azéma, Karen E. Daniels
{"title":"Loading-dependent microscale measures control bulk properties in granular material: an experimental test of the Stress-Force-Fabric relation","authors":"Carmen L. Lee, Ephraim Bililign, Emilien Azéma, Karen E. Daniels","doi":"arxiv-2409.08140","DOIUrl":null,"url":null,"abstract":"The bulk behaviour of granular materials is tied to its mesoscale and\nparticle-scale features: strength properties arise from the buildup of various\nanisotropic structures at the particle-scale induced by grain connectivity\n(fabric), force transmission, and frictional mobilization. More fundamentally,\nthese anisotropic structures work collectively to define features like the bulk\nfriction coefficient and the stress tensor at the macroscale and can be\nexplained by the Stress-Force-Fabric (SFF) relationship stemming from the\nmicroscale. Although the SFF relation has been extensively verified by discrete\nnumerical simulations, a laboratory realization has remained elusive due to the\nchallenge of measuring both normal and frictional contact forces. In this\nstudy, we analyze experiments performed on a photoelastic granular system under\nfour different loading conditions: uniaxial compression, isotropic compression,\npure shear, and annular shear. During these experiments, we record particle\nlocations, contacts, and normal and frictional forces vectors to measure the\nparticle-scale response to progressing strain. We track microscale measures\nlike the packing fraction, average coordination number and average normal force\nalong with anisotropic distributions of contacts and forces. We match the\nparticle-scale anisotropy to the bulk using the SFF relation, which is founded\non two key principles, a Stress Rule to describe the stress tensor and a Sum\nRule to describe the bulk friction coefficient; we find that the Sum and Stress\nRules accurately describe bulk measurements. Additionally, we test the\nassumption that fabric and forces transmit load equally through our granular\npackings and show that this assumption is sufficient at large strain values,\nand can be applied to areas like rock mechanics, soft colloids, or cellular\ntissue where force information is inaccessible.","PeriodicalId":501146,"journal":{"name":"arXiv - PHYS - Soft Condensed Matter","volume":"27 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - Soft Condensed Matter","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.08140","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
The bulk behaviour of granular materials is tied to its mesoscale and
particle-scale features: strength properties arise from the buildup of various
anisotropic structures at the particle-scale induced by grain connectivity
(fabric), force transmission, and frictional mobilization. More fundamentally,
these anisotropic structures work collectively to define features like the bulk
friction coefficient and the stress tensor at the macroscale and can be
explained by the Stress-Force-Fabric (SFF) relationship stemming from the
microscale. Although the SFF relation has been extensively verified by discrete
numerical simulations, a laboratory realization has remained elusive due to the
challenge of measuring both normal and frictional contact forces. In this
study, we analyze experiments performed on a photoelastic granular system under
four different loading conditions: uniaxial compression, isotropic compression,
pure shear, and annular shear. During these experiments, we record particle
locations, contacts, and normal and frictional forces vectors to measure the
particle-scale response to progressing strain. We track microscale measures
like the packing fraction, average coordination number and average normal force
along with anisotropic distributions of contacts and forces. We match the
particle-scale anisotropy to the bulk using the SFF relation, which is founded
on two key principles, a Stress Rule to describe the stress tensor and a Sum
Rule to describe the bulk friction coefficient; we find that the Sum and Stress
Rules accurately describe bulk measurements. Additionally, we test the
assumption that fabric and forces transmit load equally through our granular
packings and show that this assumption is sufficient at large strain values,
and can be applied to areas like rock mechanics, soft colloids, or cellular
tissue where force information is inaccessible.