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This study deals with transport of solutes through a saturated sub-surface rock formation with well-defined horizontal parallel fractures. For this purpose, a simplified conceptual model consisting of a single fracture and its associated rock-matrix is considered in the presence of a fracture-skin in order to study the mobility and mixing of solutes along the fracture. In this paper, a coupled fracture-skin-matrix system is modeled numerically using finite difference method in a pseudo two-dimensional domain with a constant continuous source at fracture inlet. Flow and transport processes are considered parallel to the fracture axis, while the transport processes in fracture-skin as well as in rock-matrix are considered perpendicular to the fracture axis. Having obtained the concentration distribution along the fracture, method of spatial moments is employed to study the mobility and spreading of solutes. Sensitivity analyses have been done to understand the effect of various fracture-skin parameters like porosity, thickness, and diffusion coefficient. Further, the influence of non-linear sorption and radioactive decaying of solutes are carried out for different sorption intensities and decay constants. Results suggest that the presence of fracture-skin significantly influences the mobility and spreading of solutes along the fracture in comparison with a coupled fracture-matrix system without fracture-skin. 相似文献
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A numerical model is developed for investigating the evolution of fracture permeability in a coupled fracture-matrix system in the presence of fracture-skin with simultaneous colloidal and bacterial tr... 相似文献
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N. V. Chalapathi Rao Anup K. Sinha Suresh Kumar Rajesh K. Srivastava 《Journal of the Geological Society of India》2013,81(6):733-736
We report a rare accessory groundmass mineral of K-rich titanate, having a composition close to that of potassium triskaidecatitanate (K2Ti13O27), from an underground drill-core sample of ultrapotassic rock from southwestern part of the Jharia coal field in the Damodar valley, at the northern margin of the Singhbhum craton, Eastern India. Potassium triskaidecatitanate is regarded as a typomorphic mineral of orangeites (Group II kimberlites) of Kaapvaal craton, southern Africa, and its occurrence in the Jharia ultrapotassic rock is significant since ultrapotassic suite of rocks elsewhere from the Damodar valley have been recently suggested to be peralkaline lamproites based on mineral-genetic classification. The important role played by a unique geodynamic setting (involving a thinned metasomatised lithospheric mantle and inheritance of an Archaean subduction component) at the northern margin of the Singhbhum craton in deciding the petrological diversity of the early Cretaceous ultrapotassic intrusives from the Damodar valley is highlighted in this study. 相似文献
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In this study, the behavior of thermal fronts along the fracture is studied in the presence of fracture-skin in a coupled
fracture-matrix system. Cold water is injected into the fracture, which advances gradually towards production well, while
extracting heat from the surrounding reservoir matrix. The heat conduction into the fracture-skin and the rock-matrix from
the high permeability fracture is assumed to be one dimensional perpendicular to the axis of fluid flow along the fracture.
Constant temperature cold water is injected through an injection well at the fracture inlet. The fluid flow takes place along
the horizontal fracture which ensures connectivity between the injection and production wells. Since the rock-matrix is assumed
to be tight, the permeability of fracture-skin as well as the rock-matrix is neglected. The present study focuses on the heat
flux transfer at the fracture-skin interface as against the earlier studies on fracture-matrix interface, and the sensitivity
of additional heterogeneity in the form of fracture skin in a conventional fracture-matrix coupled system is studied. The
behavior of thermal fronts for various thermal conductivity values of the fracture-skin and rock-matrix is analyzed. Spatial
moment analysis is performed on the thermal distribution profiles resulting from numerical studies in order to investigate
the impact on mobility and dispersion behavior of the fluid in the presence of fracture-skin. The presence of fracture skin
affects the heat transfer significantly in the coupled fracture-matrix system. The lower order spatial moments indicate that
the effective thermal velocity increases with increase in skin thermal conductivity and a significant thermal dispersion is
observed at the inlet of the fracture owing to the high thermal conductivity of the fracture-skin at the early stages. Furthermore
the higher spatial moments indicate that the asymmetricity increases with decrease in skin thermal conductivity unlike the
case with half fracture aperture and fluid velocity and the kurtosis is maximum with higher skin thermal conductivity which
implies enhanced heat extraction from the fracture-skin into the fracture. Results suggest that the amount of heat extraction
by the circulating fluid within the fracture from the reservoir not only depends on the rock-matrix module of the reservoir
characteristics but also the fracture-skin characteristics of the system and subsequently influence the reservoir efficiency. 相似文献