Permeability of Microcracked Solids with Random Crack Networks: Role of Connectivity and Opening Aperture

Effective permeability is an essential parameter for describing fluid flow through fractured rock masses. This study investigates the ability of classical inclusion-based effective medium models (following the work of Saevik et al. in Transp Porous Media 100(1):115-142, 2013. doi:10.1007/s11242-013-0208-0) to predict this permeability, which depends on several geometric properties of the fractures/networks. This is achieved by comparison of various effective medium models, such as the symmetric and asymmetric self-consistent schemes, the differential scheme, and Maxwell's method, with the results of explicit numerical simulations of mono-and poly-disperse isotropic fracture networks embedded in a permeable rock matrix. Comparisons are also made with the Hashin-Shtrikman bounds, Snow's model, and Mourzenko's heuristic model (Mourzenko et al. in Phys Rev E 84:036-307, 2011. doi:10.1103). This problem is characterised by two small parameters, the aspect ratio of the spheroidal fractures, α, and the ratio between matrix and fracture permeability, κ. Two different regimes can be identified, corresponding to α/κ < 1 and α/κ > 1. The lower the value of α/κ, the more significant is flow through the matrix. Due to differing flow patterns, the dependence of effective permeability on fracture density differs in the two regimes. When α/κ 1, a distinct percolation threshold is observed, whereas for α/κ 1, the matrix is sufficiently transmissive that such a transition is not observed. The self-consistent effective medium methods show good accuracy for both mono-and polydisperse isotropic fracture networks. Mourzenko's equation is very accurate, particularly for monodisperse networks. Finally, it is shown that Snow's model essentially coincides with the Hashin-Shtrikman upper bound.

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“…Mourzenko et al 2011;Saevik et al 2014;Li and Li 2015). The one used here is common, particularly in the context of effective medium models.…”

Section: Characterisation Of Fractures and Fracture Networkmentioning

confidence: 99%

Inclusion-Based Effective Medium Models for the Permeability of a 3D Fractured Rock Mass

et al. 2016

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“…In light of these limitations, researchers have turned to modelling as an alternative method for studying microcracks. The formation of microcracks, their effects on mass transport and correlations to aggregate properties have been modelled in two-dimensions [23][24][25][26][27]. 3D models have also been used to study the effects of microcracks on the diffusivity and permeability of concrete [28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Analysis of autogenous shrinkage-induced microcracks in concrete from 3D images

Mac

Yio

Wong

et al. 2021

Cement and Concrete Research

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“…Since the onsets of most deteriorations in concrete are highly related to gas and/or water transport, the gas permeability and capillary sorptivity are two fundamental quantities: the gas permeability depicts the transport rate of gas phase in pore network of concrete (Dullien, 1992), while the capillary sorptivity reflects the transport rate of liquid phase in pores of concrete (Sabir et al, 1998). These two quantities are considered as the performance indicators of durability for cement-based materials (Li et al, 2015(Li et al, , 2018. Physically, penetration of gas or water through a porous medium requires connected pore networks providing percolation paths, and thus the pore structure of cementbased materials plays a critical role in their transport properties.…”

Section: Introductionmentioning

confidence: 99%

Relationships between microstructure and transport properties in mortar containing recycled ceramic powder

Liu

You

et al. 2020

Journal of Cleaner Production

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Sustainable utilization of ceramic wastes in construction has gained increasing interest, but the microstructure and transport properties of ceramic-modified construction materials remain to be explored before in-situ engineering application. This paper presents an experimental study on microstructure, mechanical properties and transport properties of cement mortars containing different percentages of ceramic powders (CPs) up to 40%. Microstructure of CP-cement mortars was measured using mercury intrusion porosimetry, water vapor sorption isotherm and scanning electron microscopy techniques. Mechanical properties including compressive strength and flexural strength as well as transport properties including gas permeability and capillary sorptivity were measured. Results indicate that ceramic powder can greatly refine the pore structure of CP-cement mortars. Because of the homogenization and densification effects of ceramic powder on mortar matrices and interfacial transition zones, the compressive and flexural strengths of CP-cement mortars at 180 d are around 80 MPa and 10 MPa, respectively. Both gas permeability and capillary sorptivity decrease substantially as ceramic powder content increases and exhibit linear correlations with pore structure characteristics such as total porosity and critical pore size. Ceramic powder can lower the manufacture costs of concrete and obtain better durability. Therefore, ceramic powder can be considered as a promising supplementary material to develop sustainable and durable cement-based materials for future engineering applications.

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Permeability of Microcracked Solids with Random Crack Networks: Role of Connectivity and Opening Aperture

Cited by 25 publications

References 46 publications

Inclusion-Based Effective Medium Models for the Permeability of a 3D Fractured Rock Mass

Inclusion-Based Effective Medium Models for the Permeability of a 3D Fractured Rock Mass

Analysis of autogenous shrinkage-induced microcracks in concrete from 3D images

Relationships between microstructure and transport properties in mortar containing recycled ceramic powder

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