Your search keyword '"Qajar, Jafar"' showing total 4 results

1. Reactive flow in carbonate cores via digital core analysis

Author

Qajar, Jafar

Subjects

Carbonate rocks, Microporosity, Reactive flow, Digital core analysis, Deposition, X-ray micro-computed tomography, Dissolution

Abstract

The transport of fluids accompanying chemical reactions in porous rocks pre-sents a complex problem that is central in a wide variety of geochemical processes such as acidizing of petroleum reservoirs, geological storage of CO2 and contaminant transport in groundwater resources. These processes often induce substantial changes in pore structure which, in turn, may significantly change petrophysical and transport properties of the rock. A better understanding of reactive transport at the pore scale can, for example, potentially lower the risk of costly mistakes in the development of hydrocarbon reservoirs and lead to more sound environmental policy for storage of hazardous materialsis. This thesis characterizes the evolution of pore structure and transport properties of real rocks under reactive flow using the emerging technique of X-ray micro-computed tomography (μ-CT). In this thesis, we develop a framework for the characterization of pore scale reactive flow in the presence of microporosity, and apply it to carbonates since these rocks are much more susceptible to alteration than sandstones when exposed to the flow of reactive fluids. We describe the experimental and computational developments that allow imaging of pore-scale structural evolutions in core material. The evolution of pore types and interconnectivity are analysed via µ-CT images for two broad dissolution patterns, namely uniform and wormhole-like patterns. A novel method based on the three-phase segmentation of normalized images, microporosity assignment and 2D histogram of image intensities is developed to formulate voxel-based evolution scenarios during reactive flow. The developed evolution scenarios essentially represent regions of the sample where the void fraction of voxels increases, decreases or remains unchanged. The proposed approach incorporates both the resolvable porosity and the subresolution porosity into the voxel-by-voxel study of the reactive flow-induced microstructural changes. Parallel numerical calculations of morphological and transport properties and experimental measurements allow to use pore-scale physics to understand the cause of anomalies in core-scale behaviour. We discuss the effect of variations in pore connectivity and critical pore-throat diameter on changes in the transport properties of the core. The results provide important insights into the mechanisms governing pore-scale reactive displacement and the evolution of rock properties.

Published

2012

2. Characterization of reactive flow-induced evolution of carbonate rocks using digital core analysis - part 2: Calculation of the evolution of percolation and transport properties.

Author

Qajar, Jafar and Arns, Christoph H.

Subjects

*CARBONATE rocks, *X-ray computed microtomography, *DISSOLUTION (Chemistry), *PERCOLATION, *PERMEABILITY, *ELECTRIC conductivity, *MICROPOROSITY

Abstract

Percolation of reactive fluids in carbonate rocks affects the rock microstructure and hence changes the rock macroscopic properties. In Part 1 paper, we examined the voxel-wise evolution of microstructure of the rock in terms of mineral dissolution/detachment, mineral deposition, and unchanged regions. In the present work, we investigate the relationships between changes in two characteristic transport properties, i.e. permeability and electrical conductivity and two critical parameters of the pore phase, i.e. the fraction of the pore space connecting the inlet and outlet faces of the core sample and the critical pore-throat diameter. We calculate the aforementioned properties on the images of the sample, wherein a homogeneous modification of pore structure occurred in order to ensure the representativeness of the calculated transport properties at the core scale. From images, the evolution of pore connectivity and the potential role of micropores on the connectivity are quantified. It is found that the changing permeability and electrical conductivity distributions along the core length are generally in good agreement with the longitudinal evolution of macro-connected macroporosity and the critical pore-throat diameter. We incorporate microporosity into critical length and permeability calculations and show how microporosity locally plays a role in permeability. It is shown that the Katz-Thompson model reasonably predicts the post-alteration permeability in terms of pre-alteration simulated parameters. This suggests that the evolution of permeability and electrical conductivity of the studied complex carbonate core are controlled by the changes in the macro-connected macroporosity as well as the smallest pore-throats between the connected macropores. [ABSTRACT FROM AUTHOR]

Published

2017

3. Characterization of reactive flow-induced evolution of carbonate rocks using digital core analysis- part 1: Assessment of pore-scale mineral dissolution and deposition.

Author

Qajar, Jafar and Arns, Christoph H.

Subjects

*CARBONATE rocks, *REACTIVE flow, *SEDIMENTATION & deposition, *X-ray computed microtomography, *MICROPOROSITY

Abstract

The application of X-ray micro-computed tomography (μ-CT) for quantitatively characterizing reactive-flow induced pore structure evolution including local particle detachment, displacement and deposition in carbonate rocks is investigated. In the studies conducted in this field of research, the experimental procedure has involved alternating steps of imaging and ex-situ core sample alteration. Practically, it is impossible to return the sample, with micron precision, to the same position and orientation. Furthermore, successive images of a sample in pre- and post-alteration states are usually taken at different conditions such as different scales, resolutions and signal-to-noise ratios. These conditions accompanying with subresolution features in the images make voxel-by-voxel comparisons of successive images problematic. In this paper, we first address the respective challenges in voxel-wise interpretation of successive images of carbonate rocks subject to reactive flow. Reactive coreflood in two carbonate cores with different rock types are considered. For the first rock, we used the experimental and imaging results published by Qajar et al. (2013) which showed a quasi-uniform dissolution regime. A similar reactive core flood was conducted in the second rock which resulted in wormhole-like dissolution regime. We particularly examine the major image processing operations such as transformation of images to the same grey-scale, noise filtering and segmentation thresholding and propose quantitative methods to evaluate the effectiveness of these operations in voxel-wise analysis of successive images of a sample. In the second part, we generalize the methodology based on the three-phase segmentation of normalized images, microporosity assignment and 2D histogram of image intensities to estimate grey-scale changes of individual image voxels for a general case where the greyscale images are segmented into arbitrary number of phases. The results show that local (voxel-based) porosity changes can be decomposed into local mineral dissolution and deposition. Moreover, it is found that the microporosity evolutions are differently distributed in the samples after the reactive coreflood experiments. In the last part of the paper, for the case of quasi-uniform dissolution, we combine the tomographic images with numerical calculations of permeability along the core to characterize the relationship between changes in permeability and the fractions of the mineral dissolved and deposited. A consistency is found between the calculated longitudinal permeability changes and the quantified distribution of mineral dissolved and deposited along the sample. [ABSTRACT FROM AUTHOR]

Published

2016

4. A comparative study of micro-CT and mercury intrusion techniques for predicting permeability and surface area evolution during chemical dissolution.

Author

Qajar, Jafar and Arns, Christoph H.

Subjects

*SURFACE area, *X-ray computed microtomography, *PERMEABILITY, *POROSITY, *MERCURY, *MICROPOROSITY

Abstract

• Effects of chemical dissolution on pore space was explored by μ-CT and MIP methods. • The evolution of pore size was examined by experimental and simulated MIP curves. • Impact of micropores on pore surface area was quantified by combining μ-CT and MIP. • Permeability changes were controlled by macroporosity and critical pore diameter. In this paper, we report on experimental and computational studies investigating the evolution of pore structure and permeability of a microporous carbonate rock during chemical dissolution using information provided from X-ray micro-computed tomography (µ-CT) and mercury intrusion porosimetry (MIP) techniques. We consider a chemical dissolution in a core sample by a nonacidic solution wherein a quasi-uniform modification of pore structure occurred. First, we conduct a comparative analysis on the capabilities and limitations of the µ-CT and MIP methods to quantify the evolution of pore size and pore surface area. In particular, we incorporate micropores into the calculations of the pore size-related parameters to highlight the uncertainties that ignoring microporosity causes. In the second part of the paper, we present predictive results on the fractional changes in the permeability of the rock using the Katz-Thompson (KT) and Kozeny-Carman (KC) models. The predictions are based on two characteristic parameters of the pore phase, i.e., the critical pore diameter and the specific pore surface area, and two characteristic macro-scale properties, i.e., porosity and formation factor, all calculated from both the MIP and µ-CT methods. The predicted changes in permeability are compared with those calculated directly on the images using the lattice-Boltzmann (LB) flow simulation on segmented images. The effect of changes in microporosity is also assessed to investigate its role in permeability evolution. The results showed that the KT model could reasonably predict the fractional changes in permeability in terms of the pore structure and macroscale parameters calculated from the MIP and µ-CT methods. [ABSTRACT FROM AUTHOR]

Published

2022