Micromechanical approach to swelling behavior of capillary‐porous media with coupled physics

Eghbalian, Mahdad; Pouragha, Mehdi; Wan, Richard

doi:10.1002/nag.2867

Cited by 14 publications

(8 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The solutions to the boundary value problems in Equations (1) and (2) give the local microscopic fields, including the stress and fluid velocity fields, in terms of the prescribed macrostrain and macropressure gradient. The average stress and velocity in the REV are then obtained as:…”

Section: Homogenization Problemmentioning

confidence: 99%

“…For an oblate spheroid having a very low aspect ration ( ≪ 1), ie, penny-shaped, the Eshelby's tensor, when expanded to the first order in , is as follows: in terms of microcrack aspect ratio = ℎ∕ (2 ). A first-order expansion in is considered, which is valid for aspect ratios ≪ 1.…”

Section: C3 Oblate Spheroidmentioning

confidence: 99%

“…In contrast with the various available approaches for modeling brittle microcracking in rocks (see different modeling approaches of geomaterials in Ref. 2), we herein focus on microstructural aspects and therefore pursue a multiscale modeling strategy where the behavioral equations of rock as a three-scale material are upscaled to arrive at a closed-form constitutive model. Such a multiscale modeling effort can be indeed very challenging considering the inherent complexities of the rock microstructure.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A three‐dimensional multiscale damage‐poroelasticity model for fractured porous media

Eghbalian

Pouragha

Wan

2020

Num Anal Meth Geomechanics

Self Cite

View full text Add to dashboard Cite

The paper investigates the failure of brittle rocks within a multiscale/multiphysics computational modeling framework so as to explicitly incorporate both microstructural and hydromechanical aspects in their overall (nonlinear) fracture behavior. Herein, the rock is idealized as a microfissured porous medium via a representative elementary volume (REV) containing distributed oblate spheroidal open microcracks and spheroidal nanopores at the lower scales. A two-scale analytical homogenization procedure is then performed on the REV, assuming a saturated pore space across the scales. The end result is a microstructurally enriched continuum damage-poroelasticity constitutive model within the generalized Biot's framework that inherits the underlying small-scale characteristics. A set of damage tensors is derived based on the directional density distribution of microcracks that operate on both the poromechanical and hydraulic properties. Microstructural evolution is modeled following changes in microcrack length, aperture, and number density, including nanoporosity. To this end, a robust localization procedure is used that accurately captures the macroscopic softening due to microcracking events, leading to a nonlinear (but path-independent) model. To investigate the baseline features of the model, including the salient effects of microcracking on induced anisotropy and deterioration of poroelastic properties, numerical results of material point-based computations are discussed in detail. Finally, predictions of the current model are validated against experiments on Fontainebleau sandstone.

show abstract

Section: Homogenization Problemmentioning

confidence: 99%

Section: C3 Oblate Spheroidmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A three‐dimensional multiscale damage‐poroelasticity model for fractured porous media

Eghbalian

Pouragha

Wan

2020

Num Anal Meth Geomechanics

Self Cite

View full text Add to dashboard Cite

show abstract

“…Studies have shown that montmorillonite plays an important role in the swelling and shrinking of expansive soil. Starting with nanolevel minerals is a prerequisite to fully understand and clarify its deformation and destruction [11]. However, it is highly difficult to test the interaction between the solid and liquid molecules of crystal layer by experimental methods, which hinders the further development of clay mineralogy to a certain extent.…”

Section: Introductionmentioning

confidence: 99%

A Simulation Study on the Swelling and Shrinking Behaviors of Nanosized Montmorillonite Based on Monte Carlo and Molecular Dynamics

et al. 2021

View full text Add to dashboard Cite

Montmorillonite is the main mineral source for the swelling and shrinking of expansive soils. The macroscopic phenomena of soil are affected by the action of deep-level nanosized minerals. In order to illustrate the nanoscale mechanism from the molecular level, a combination of Monte Carlo and molecular dynamics was used to explore the swelling and shrinking characteristics of montmorillonite. The results showed that the basal spacing, free swelling ratio, and void ratio were positively correlated with water content but were inversely proportional to the change of CEC. The hysteresis phenomena of swelling and shrinking were the most significant at a water content of 40%. Compared with the expansive soil, the nanoscale shrinkage curve of montmorillonite also included three stages of normal shrinkage, residual shrinkage, and no shrinkage. The relative concentration of water molecules conveyed information such as the thickness and position of the hydration film and explained the difference in swelling and shrinking caused by the above variables. The changes in the number and length of hydrogen bonds revealed the order of formation and the process of destruction of hydrogen bonds during the reaction. The similarity of the trends between the basal spacing, binding energy, and the number of hydrogen bonds indicated that the swelling and shrinking of the crystal layer are a reflection of the molecular interaction, and the hydrogen bonding is particularly critical.

show abstract

“…These challenges apply to model unsaturated soils as a multiscale multiphysics problem. () To formulate a high‐fidelity physics‐based multiscale computational framework for unsaturated soils, we first need to obtain the fundamental physical information at the interfacial scale of such materials.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics modeling of a partially saturated clay‐water system at finite temperature

Song

Wang

2019

Num Anal Meth Geomechanics

View full text Add to dashboard Cite

Summary The mechanical and hydraulic properties of unsaturated clay under nonisothermal conditions have practical implications in geotechnical engineering applications such as geothermal energy harvest, landfill cover design, and nuclear waste disposal facilities. The water menisci among clay particles impact the mechanical and hydraulic properties of unsaturated clay. Molecular dynamics (MD) modeling has been proven to be an effective method in investigating clay structures and their hydromechanical behavior at the atomic scale. In this study, we examine the impact of temperature increase on the capillary force and capillary pressure of the partially saturated clay‐water system through high‐performance computing. The water meniscus formed between two parallel clay particles is studied via a full‐scale MD modeling at different elevated temperatures. The numerical results have shown that the temperature increase impacts the capillary force, capillary pressure, and contact angle at the atomic scale. The capillary force on the clay particle obtained from MD simulations is also compared with the results from the macroscopic theory. The full‐scale MD simulation of the partially saturated clay‐water system can not only provide a fundamental understanding of the impact of temperature on the interface physics of such system at the atomic scale, but also has practical implication in formulating physics‐based multiscale models for unsaturated soils by providing interface physical properties of such materials directly through high‐performance computing.

show abstract

Micromechanical approach to swelling behavior of capillary‐porous media with coupled physics

Cited by 14 publications

References 58 publications

A three‐dimensional multiscale damage‐poroelasticity model for fractured porous media

A three‐dimensional multiscale damage‐poroelasticity model for fractured porous media

A Simulation Study on the Swelling and Shrinking Behaviors of Nanosized Montmorillonite Based on Monte Carlo and Molecular Dynamics

Molecular dynamics modeling of a partially saturated clay‐water system at finite temperature

Contact Info

Product

Resources

About