Effect of Cumulative Surface on Pore Development in Chalk

Y. Yang; S. S. Hakim; S. Bruns; K. Uesugi; S. L. S. Stipp; H. O. Sorensen

doi:10.1029/2018WR023756

Effect of Cumulative Surface on Pore Development in Chalk

Y. Yang, S. S. Hakim, S. Bruns, K. Uesugi, S. L. S. Stipp, H. O. Sorensen

1 Citation (Scopus)

Abstract

Pore development in natural porous media, as a result of mineral dissolution in flowing fluid, generates complex microstructures. Although the underlying dynamics of fluid flow and the kinetics of the dissolution reactions have been carefully analyzed in many scenarios, it remains interesting to ask if the preferentially developed flow paths share certain general petrophysical properties. Here we combine in situ X-ray imaging with network modeling to study pore development in chalk driven by acidic fluid flow under ambient condition. We show that the trajectory of a growing pore correlates with the flow path that minimizes cumulative surface—the overall surface area available to fluid within the residence time—calculated along streamlines. This correlation is not a coincidence because cumulative surface determines conversion of reactant and thus defines the position of dissolution front. Model simulations show that, as fluid channelizes, the growth of the leading pore in the flow direction is guided by migration of the most far-reaching dissolution front, even in an ever-changing flow field. In addition, we present a complete tomographic time series of microstructure erosion and show a good accord between the in situ observation and the model simulation. Our results suggest that the microscopic pore development is a deterministic process while being sensitive to stochastic perturbations to the migrating dissolution front.

Original language	English
Journal	Water Resources Research
Volume	55
Issue number	6
Pages (from-to)	4801-4819
ISSN	0043-1397
DOIs	https://doi.org/10.1029/2018WR023756
Publication status	Published - Jun 2019

Keywords

cumulative surface
chalk
tomography
microstructure evolution
dissolution front

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10.1029/2018WR023756

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@article{8e93298760c049e18a841ea32aed63bd,

title = "Effect of Cumulative Surface on Pore Development in Chalk",

abstract = "Pore development in natural porous media, as a result of mineral dissolution in flowing fluid, generates complex microstructures. Although the underlying dynamics of fluid flow and the kinetics of the dissolution reactions have been carefully analyzed in many scenarios, it remains interesting to ask if the preferentially developed flow paths share certain general petrophysical properties. Here we combine in situ X-ray imaging with network modeling to study pore development in chalk driven by acidic fluid flow under ambient condition. We show that the trajectory of a growing pore correlates with the flow path that minimizes cumulative surface—the overall surface area available to fluid within the residence time—calculated along streamlines. This correlation is not a coincidence because cumulative surface determines conversion of reactant and thus defines the position of dissolution front. Model simulations show that, as fluid channelizes, the growth of the leading pore in the flow direction is guided by migration of the most far-reaching dissolution front, even in an ever-changing flow field. In addition, we present a complete tomographic time series of microstructure erosion and show a good accord between the in situ observation and the model simulation. Our results suggest that the microscopic pore development is a deterministic process while being sensitive to stochastic perturbations to the migrating dissolution front.",

keywords = "cumulative surface, chalk, tomography, microstructure evolution, dissolution front",

author = "Y. Yang and Hakim, {S. S.} and S. Bruns and K. Uesugi and Stipp, {S. L. S.} and Sorensen, {H. O.}",

year = "2019",

month = jun,

doi = "10.1029/2018WR023756",

language = "English",

volume = "55",

pages = "4801--4819",

journal = "Water Resources Research",

issn = "0043-1397",

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TY - JOUR

T1 - Effect of Cumulative Surface on Pore Development in Chalk

AU - Yang, Y.

AU - Hakim, S. S.

AU - Bruns, S.

AU - Uesugi, K.

AU - Stipp, S. L. S.

AU - Sorensen, H. O.

PY - 2019/6

Y1 - 2019/6

N2 - Pore development in natural porous media, as a result of mineral dissolution in flowing fluid, generates complex microstructures. Although the underlying dynamics of fluid flow and the kinetics of the dissolution reactions have been carefully analyzed in many scenarios, it remains interesting to ask if the preferentially developed flow paths share certain general petrophysical properties. Here we combine in situ X-ray imaging with network modeling to study pore development in chalk driven by acidic fluid flow under ambient condition. We show that the trajectory of a growing pore correlates with the flow path that minimizes cumulative surface—the overall surface area available to fluid within the residence time—calculated along streamlines. This correlation is not a coincidence because cumulative surface determines conversion of reactant and thus defines the position of dissolution front. Model simulations show that, as fluid channelizes, the growth of the leading pore in the flow direction is guided by migration of the most far-reaching dissolution front, even in an ever-changing flow field. In addition, we present a complete tomographic time series of microstructure erosion and show a good accord between the in situ observation and the model simulation. Our results suggest that the microscopic pore development is a deterministic process while being sensitive to stochastic perturbations to the migrating dissolution front.

AB - Pore development in natural porous media, as a result of mineral dissolution in flowing fluid, generates complex microstructures. Although the underlying dynamics of fluid flow and the kinetics of the dissolution reactions have been carefully analyzed in many scenarios, it remains interesting to ask if the preferentially developed flow paths share certain general petrophysical properties. Here we combine in situ X-ray imaging with network modeling to study pore development in chalk driven by acidic fluid flow under ambient condition. We show that the trajectory of a growing pore correlates with the flow path that minimizes cumulative surface—the overall surface area available to fluid within the residence time—calculated along streamlines. This correlation is not a coincidence because cumulative surface determines conversion of reactant and thus defines the position of dissolution front. Model simulations show that, as fluid channelizes, the growth of the leading pore in the flow direction is guided by migration of the most far-reaching dissolution front, even in an ever-changing flow field. In addition, we present a complete tomographic time series of microstructure erosion and show a good accord between the in situ observation and the model simulation. Our results suggest that the microscopic pore development is a deterministic process while being sensitive to stochastic perturbations to the migrating dissolution front.

KW - cumulative surface

KW - chalk

KW - tomography

KW - microstructure evolution

KW - dissolution front

U2 - 10.1029/2018WR023756

DO - 10.1029/2018WR023756

M3 - Journal article

SN - 0043-1397

VL - 55

SP - 4801

EP - 4819

JO - Water Resources Research

JF - Water Resources Research

IS - 6

ER -

Effect of Cumulative Surface on Pore Development in Chalk

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Keywords

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