Early-stage hypogene karstification in a mountain hydrologic system: A coupled thermohydrochemical model incorporating buoyant convection

The early stage of hypogene karstification is investigated using a coupled thermohydrochemical model of a mountain hydrologic system, in which water enters along a water table and descends to significant depth (∼1 km) before ascending through a central high‐permeability fracture. The model incorpora...

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Bibliographic Details
Published in:Water resources research 2013-09, Vol.49 (9), p.5880-5899
Main Authors: Chaudhuri, A., Rajaram, H., Viswanathan, H.
Format: Article
Language:English
Subjects:
buoyant convection
calcite
Convection
coupled process
dissolution kinetics
Groundwater
hypogene karst
Karst
Limestone
Mass transfer
Permeability
Preferential flow
Solubility
Transmissivity
Water depth
Water table
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Summary:The early stage of hypogene karstification is investigated using a coupled thermohydrochemical model of a mountain hydrologic system, in which water enters along a water table and descends to significant depth (∼1 km) before ascending through a central high‐permeability fracture. The model incorporates reactive alteration driven by dissolution/precipitation of limestone in a carbonic acid system, due to both temperature‐ and pressure‐dependent solubility, and kinetics. Simulations were carried out for homogeneous and heterogeneous initial fracture aperture fields, using the FEHM (Finite Element Heat and Mass Transfer) code. Initially, retrograde solubility is the dominant mechanism of fracture aperture growth. As the fracture transmissivity increases, a critical Rayleigh number value is exceeded at some stage. Buoyant convection is then initiated and controls the evolution of the system thereafter. For an initially homogeneous fracture aperture field, deep well‐organized buoyant convection rolls form. For initially heterogeneous aperture fields, preferential flow suppresses large buoyant convection rolls, although a large number of smaller rolls form. Even after the onset of buoyant convection, dissolution in the fracture is sustained along upward flow paths by retrograde solubility and by additional “mixing corrosion” effects closer to the surface. Aperture growth patterns in the fracture are very different from those observed in simulations of epigenic karst systems, and retain imprints of both buoyant convection and preferential flow. Both retrograde solubility and buoyant convection contribute to these differences. The paper demonstrates the potential value of coupled models as tools for understanding the evolution and behavior of hypogene karst systems. Key Points Hypogene karstification due to retrograde solubility of calcite Onset of buoyant convection after sufficient permeability growth Competition between buoyant convection & preferential flow in heterogeneous case
ISSN:0043-1397
1944-7973
DOI:10.1002/wrcr.20427