Thermal Ensemble for Stresses in Dense Suspensions
ORAL
Abstract
We develop a predictive framework for the macroscopic stress properties of dense suspensions
in two dimensions, based on correlations in a dual space representing forces. Working with the
ensemble of steady state configurations obtained from simulations of suspensions, we find an
emerging anisotropy in the pair correlation function in force space as the confining shear stress
(σxy) and the packing fraction (φ) are varied. Using these microscopic correlations, we build
a statistical theory of the forces and relate this to the macroscopic stress tensor of the system.
We find that (i) the stress anisotropy τ /P decreases as φ is increased and (ii) the normal stress
N1 = σxx− σyy changes sign near the discontinuous shear thickening transition (DST). We provide
evidence for a first order transition occurring near the DST point, with a coexistence of ‘fluid’
regions with low stresses and ‘solid’ regions with high stresses.
in two dimensions, based on correlations in a dual space representing forces. Working with the
ensemble of steady state configurations obtained from simulations of suspensions, we find an
emerging anisotropy in the pair correlation function in force space as the confining shear stress
(σxy) and the packing fraction (φ) are varied. Using these microscopic correlations, we build
a statistical theory of the forces and relate this to the macroscopic stress tensor of the system.
We find that (i) the stress anisotropy τ /P decreases as φ is increased and (ii) the normal stress
N1 = σxx− σyy changes sign near the discontinuous shear thickening transition (DST). We provide
evidence for a first order transition occurring near the DST point, with a coexistence of ‘fluid’
regions with low stresses and ‘solid’ regions with high stresses.
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Presenters
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Jetin E Thomas
Martin A. Fisher School of Physics, Brandeis University
Authors
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Jetin E Thomas
Martin A. Fisher School of Physics, Brandeis University
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Kabir Ramola
Martin A. Fisher School of Physics, Brandeis University
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Abhinendra Singh
Benjamin Levich Institute, CUNY City College of New York, Levich Institute, City College of New York CUNY
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Jeffrey Morris
CUNY City College of New York, Department of Chemical Engineering, Levich Institute, City College of New York CUNY
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Bulbul Chakraborty
Physics, Brandeis University, Brandeis University, Martin A. Fisher School of Physics, Brandeis University, Martin A School of Physics, Brandeis University