A Geo‐Structurally Based Correction Factor for Apparent Dissolution Rates in Fractured Media

Field measurements of apparent geochemical weathering reaction rates in subsurface fractured porous media are known to deviate from laboratory measurements by multiple orders of magnitude. To date, there is no geologically based explanation for this discrepancy that can be used to predict reaction r...

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Bibliographic Details
Published in:Geophysical research letters 2022-08, Vol.49 (15), p.n/a
Main Authors: Hyman, Jeffrey D., Navarre‐Sitchler, Alexis, Andrews, Elizabeth, Sweeney, Matthew R., Karra, Satish, Carey, J. William, Viswanathan, Hari S.
Format: Article
Language:English
Subjects:
Accuracy
apparent dissolution rates
Crack propagation
Dissolution
Dissolving
Fluid dynamics
Fluid flow
Fluids
Fracture mechanics
fracture network
Fracture permeability
Geochemistry
Geological structures
Geology
GEOSCIENCES
Laboratories
Mathematical models
Minerals
Numerical simulations
Permeability
Porous media
reactive transport modeling
Simulation
subsurface flow and transport
Transport
Weathering
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Summary:Field measurements of apparent geochemical weathering reaction rates in subsurface fractured porous media are known to deviate from laboratory measurements by multiple orders of magnitude. To date, there is no geologically based explanation for this discrepancy that can be used to predict reaction rates in field systems. Proposed correction factors are typically based on ad hoc characterizations related to geochemical kinetic models. Through a series of high‐fidelity reactive transport simulations of mineral dissolution within explicit 3D discrete fracture networks, we are able to link the geo‐structural attributes with reactive transport observations. We develop a correction factor to linear transition state theory for the prediction of the apparent dissolution rate based on measurable geological properties. The modified rate law shows excellent agreement with numerical simulations, indicating that geological structure could be a primary reason for the discrepancy between laboratory and field observations of apparent dissolution rates in fractured media. Plain Language Summary Fractures are the principal conduits for fluid flow through low permeability rock in the Earth's subsurface. In many of these systems, fluids passing through the fractures are out of equilibrium with the resident minerals, and various reactions, such as dissolution and precipitation, occur. These geochemical processes change the fracture permeability and drive fracture propagation, thereby dynamically changing flows. Field measurements of apparent geochemical weathering reaction rates are lower than laboratory measurements by multiple orders of magnitude, which makes predictions of geochemical reaction rates highly uncertain. These slow apparent dissolution rates are particularly pronounced in fracture networks where geo‐structural attributes, for example, the network connectivity and fracture geometry, determine the flow field structure and dictate transport. Through a series of high‐fidelity reactive transport simulations of mineral dissolution in fractured media, we uncovered a new link between the geo‐structural attributes of the underlying fracture network with reactive transport observations. Guided by this information, we develop a correction factor to linear transition state theory to predict the apparent dissolution rate that is based on these geological attributes. The excellent agreement of the proposed model with our numerical simulations indicates that geological struct
ISSN:0094-8276
1944-8007
DOI:10.1029/2022GL099513