Micro-mechanical insights into the stress transmission in strongly aggregating colloidal gel

Author:

Gadi Man Yezaz Ahmed1ORCID,Dagur Divas Singh1ORCID,Roy Saikat1ORCID

Affiliation:

1. Department of Chemical Engineering , Indian Institute of Technology Ropar, Rupnagar, Punjab 140001, India

Abstract

Predicting the mechanical response of soft gel materials under external deformation is of paramount importance in many areas, such as foods, pharmaceuticals, solid–liquid separations, cosmetics, aerogels, and drug delivery. Most of the understanding of the elasticity of gel materials is based on the concept of fractal scaling with very few microscopic insights. Previous experimental observations strongly suggest that the gel material loses the fractal correlations upon deformation and the range of packing fraction up to which the fractal scaling can be applied is very limited. In addition, correctly implementing the fractal modeling requires identifying the elastic backbone, which is a formidable task. So far, there is no clear understanding of the gel’s elasticity at high packing fractions or the correct length scale that governs its mechanical response. In this work, we undertake extensive numerical simulations to elucidate the different aspects of stress transmission in gel materials. We observe the existence of two percolating networks of compressive and tensile normal forces close to the gel point. We also find that the probability distribution for the compressive and tensile parts normalized by their respective mean shows a universal behavior irrespective of various values of interaction potential and thermal energy and different particle size distributions. Interestingly, there are also a large number of contacts with zero normal force, and, consequently, a peak in the normal force distribution is observed at fn ≈ 0 even at higher pressures. We also identify the critical internal state parameters, such as the mean normal force, force anisotropies, and the average coordination number, and propose simple constitutive relations that relate different components of stress to internal state parameters. The agreement between our model prediction and the simulation observation is excellent. It is shown that the anisotropy in the force networks gives rise to the normal stress difference in soft gel materials. Our results strongly demonstrate that the mechanical response of the gel system is governed mainly by the particle length scale phenomena, with a complex interplay between the compressive and tensile forces at the particle contact.

Funder

Science and Engineering Research Board

Publisher

AIP Publishing

Subject

Physical and Theoretical Chemistry,General Physics and Astronomy

Cited by 4 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. Formation dynamics of branching structure in the slippery DLCA model;The Journal of Chemical Physics;2024-06-17

2. Theoretical study of kinetic arrest, shear elastic modulus, and yielding in simple biphasic colloidal mixtures;The Journal of Chemical Physics;2024-01-28

3. Colloidal gels;The Journal of Chemical Physics;2023-09-05

4. Spatial stress correlations in strong colloidal gel systems;Physical Review B;2023-07-26

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