Characterizing the Influence of Fracture Density on Network Scale Transport

Sherman, Thomas; Hyman, Jeffrey D.; Dentz, Marco; Bolster, Diogo

doi:10.1029/2019jb018547

Cited by 25 publications

(25 citation statements)

References 73 publications

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“…Sherman et al. (2020) discussed the tortuosity effect in detail and concludes that honoring the tortuosity distribution can improve model performance. Our results show that using an average tortuosity value is sufficient to capture overall transport behavior.…”

Section: Upscaled Stochastic Transport Modelmentioning

confidence: 99%

“…Many studies in the literature (Benke & Painter, 2003; Hyman et al., 2019b; Kang, Brown, et al., 2016; Le Borgne et al., 2008; Sund et al., 2016) have shown that the Lagrangian velocity series { v n }, if sampled in space, can be modeled as Markov processes. These observations have led to the development of CTRW formulations based on velocity Markov models (Dentz et al., 2016; Hakoun et al., 2019a; Kang et al., 2017; Le Borgne et al., 2008) that are able to predict anomalous transport in porous and fractured media (Comolli et al., 2019; Hyman et al., 2019b; Kang, Brown, et al., 2016; Kang et al., 2014; Le Borgne et al., 2008; Sherman et al., 2020; Sund et al., 2016). The empirical estimation of the transition matrix, equation (), from numerical or experimental data can be a challenging issue in practice (Sherman et al., 2017).…”

Section: Upscaled Stochastic Transport Modelmentioning

confidence: 99%

“…We assigned average tortuosity into the CTRW model, but the tortuosity of each particle should be different, and tortuosity will be in general smaller for particles that arrive faster. Sherman et al (2020) discussed the tortuosity effect in detail and concludes that honoring the tortuosity distribution can improve model performance. Our results show that using an average tortuosity value is sufficient to capture overall transport behavior.…”

Section: Water Resources Researchmentioning

confidence: 99%

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Anomalous Transport in Three‐Dimensional Discrete Fracture Networks: Interplay Between Aperture Heterogeneity and Injection Modes

Kang

Hyman

Han

et al. 2020

Water Resources Research

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We study how the interplay between fracture aperture heterogeneity and tracer injection mode controls fluid flow and tracer transport in three‐dimensional (3D) discrete fracture networks (DFNs). The direct 3‐D DFN simulations show that tracer injection mode has substantial effects on tracer spreading across all levels of aperture heterogeneity. The key controlling factor for effective transport is the initial Lagrangian velocity distribution, which is determined by the interplay between injection mode and aperture heterogeneity. The fundamental difference between initial Lagrangian velocity distribution and domain‐scale Eulerian velocity distribution plays a vital role in determining anomalous transport. We effectively capture the observed anomalous transport using an upscaled transport model that incorporates initial velocity distribution, stationary velocity distribution, velocity correlation length, and average advective tortuosity. With the upscaled transport model, we accurately capture the evolution of Lagrangian velocity distribution and predict longitudinal spreading in 3‐D DFN.

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Section: Upscaled Stochastic Transport Modelmentioning

confidence: 99%

Section: Upscaled Stochastic Transport Modelmentioning

confidence: 99%

Section: Water Resources Researchmentioning

confidence: 99%

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Anomalous Transport in Three‐Dimensional Discrete Fracture Networks: Interplay Between Aperture Heterogeneity and Injection Modes

Kang

Hyman

Han

et al. 2020

Water Resources Research

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“…This multiscale structural heterogeneity leads to multiscale flow channelization at length scales ranging from the entire system down to the subfracture size. At the largest scale, network density and connectivity alter the distribution of flow within the network, but this connection has only been qualitatively identified at this time (Huseby et al., 2001; Hyman & Jiménez‐Martínez, 2018; Hyman et al., 2019a; Sherman et al., 2020; Sweeney & Hyman, 2020). While it is generally accepted that a lower degree of flow channeling ought to occur in higher‐density networks, how to quantify the degree of flow channeling and link those measurements to geological features remains unclear.…”

Section: Introductionmentioning

confidence: 99%

“…For example, Sherman et al. (2020) observed that network density affected flow channeling and then studied the ability of upscaled transport models to reproduce high‐fidelity transport simulations using DFN models at these various densities. However, they did not systematically study the link between network structure attributes and flow channel formation nor develop new methods to compare flow channelization between networks.…”

Section: Introductionmentioning

confidence: 99%

Flow Channeling in Fracture Networks: Characterizing the Effect of Density on Preferential Flow Path Formation

Hyman

2020

Water Resources Research

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Flow channelization is a commonly observed phenomenon in fractured subsurface media where the flow of fluids is restricted primarily to highly transmissive fracture networks surrounded by a low-permeability rock matrix. The multiscale structural heterogeneity of these networks results in multiscale flow channelization where preferential flow paths form at length scales ranging from the entire system down to the subfracture size. We present an analysis of how one of the largest scales in fractured media, the network density, influences the degree of flow channeling that occurs using an ensemble of semigeneric three-dimensional discrete fracture network (DFN) simulations. We construct 10 DFNs, whose fracture lengths follow a power law distribution, at four densities for a total of 40 networks. We characterize their structure in terms of the network topology and geometry. Eulerian and Lagrangian observations of the steady-state flow fields obtained within the networks are used to quantify the degree of flow channelization at the network scale. We introduce a measure for the importance-ranking/hierarchy of different flow paths in the network using graph-based analysis of Lagrangian transport by which the degree of flow channeling between networks is compared. These flow observations are then linked to the structural properties of the networks. In general, network-scale flow channeling decreases as the network density increases. However, at low densities, there is more uniform flow within the entire connected network than in high-density networks. We also demonstrate how standard transport observables can be used to infer the degree of flow channelization occurring within a fracture network.

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Upscaling of solute plumes in periodic porous media through a trajectory based spatial Markov model

Janetti

Sherman

Guédon

et al. 2020

Preprint

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We propose an approach to upscale solute transport in spatially periodic porous media. Our methodology relies on pore-scale information to predict large-scale transport features, including explicit reconstruction of the solute plume, breakthrough curves at fixed distances, and spatial spreading transverse to the main flow direction. The proposed approach is grounded on the recently proposed trajectory-based spatial Markov model (tSMM), which upscales transport based on information collected from advective-diffusive particle trajectories across one periodic element. In previous works, this model has been applied solely to one-dimensional transport in a single periodic pore geometry. In this work we extend the tSMM to the prediction of multidimensional solute plumes. This is obtained by analyzing the joint space-time probability distribution associated with discrete particles, as yielded by the tSMM. By comparing numerical results from fully resolved simulations and predictions obtained with the tSMM over a wide range of Péclet numbers, we demonstrate that the proposed approach is suitable for modeling transport of conservative and linearly decaying solute species in a realistic pore space and showcase the applicability of the model to predict steady-state solute plumes. Additionally, we evaluate the model performance as a function of numerical parameters employed in the tSMM parameterization.

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Characterizing the Influence of Fracture Density on Network Scale Transport

Cited by 25 publications

References 73 publications

Anomalous Transport in Three‐Dimensional Discrete Fracture Networks: Interplay Between Aperture Heterogeneity and Injection Modes

Anomalous Transport in Three‐Dimensional Discrete Fracture Networks: Interplay Between Aperture Heterogeneity and Injection Modes

Flow Channeling in Fracture Networks: Characterizing the Effect of Density on Preferential Flow Path Formation

Upscaling of solute plumes in periodic porous media through a trajectory based spatial Markov model

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