Compaction of porous rock by dissolution on discrete stylolites:  A one-dimensional model

Luiza Angheluta; Joachim Mathiesen; Einat Aharonov

doi:10.1029/2012JB009245

Compaction of porous rock by dissolution on discrete stylolites: A one-dimensional model

Luiza Angheluta, Joachim Mathiesen, Einat Aharonov

Biocomplexity

7 Citations (Scopus)

Abstract

Compaction of sedimentary porous rock by dissolution and precipitation is a complex deformation mechanism, that is often localized on stylolites and pressure solution seams. We consider a one-dimensional model of compaction near a thin clay-rich stylolite embedded in a porous rock. Under the assumption that the clay enhances solubility, the model predicts a reactive transport away from the clay layer followed by pore cementation. The evolution of the porosity, reactant transport, and compaction rate are studied as functions of model parameters and shown to reach a stationary state. We find good agreement between the porosity distribution predicted by the model and previously reported field measurements. The model provides quantitative estimates for compaction rates on stylolitic surfaces.

Original language	English
Journal	Journal of Geophysical Research: Earth Surface
Volume	117
Pages (from-to)	B08203
Number of pages	8
ISSN	2169-9003
DOIs	https://doi.org/10.1029/2012JB009245
Publication status	Published - 1 Aug 2012

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title = "Compaction of porous rock by dissolution on discrete stylolites: A one-dimensional model",

abstract = "Compaction of sedimentary porous rock by dissolution and precipitation is a complex deformation mechanism, that is often localized on stylolites and pressure solution seams. We consider a one-dimensional model of compaction near a thin clay-rich stylolite embedded in a porous rock. Under the assumption that the clay enhances solubility, the model predicts a reactive transport away from the clay layer followed by pore cementation. The evolution of the porosity, reactant transport, and compaction rate are studied as functions of model parameters and shown to reach a stationary state. We find good agreement between the porosity distribution predicted by the model and previously reported field measurements. The model provides quantitative estimates for compaction rates on stylolitic surfaces.",

author = "Luiza Angheluta and Joachim Mathiesen and Einat Aharonov",

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T1 - Compaction of porous rock by dissolution on discrete stylolites

T2 - A one-dimensional model

AU - Angheluta, Luiza

AU - Mathiesen, Joachim

AU - Aharonov, Einat

PY - 2012/8/1

Y1 - 2012/8/1

N2 - Compaction of sedimentary porous rock by dissolution and precipitation is a complex deformation mechanism, that is often localized on stylolites and pressure solution seams. We consider a one-dimensional model of compaction near a thin clay-rich stylolite embedded in a porous rock. Under the assumption that the clay enhances solubility, the model predicts a reactive transport away from the clay layer followed by pore cementation. The evolution of the porosity, reactant transport, and compaction rate are studied as functions of model parameters and shown to reach a stationary state. We find good agreement between the porosity distribution predicted by the model and previously reported field measurements. The model provides quantitative estimates for compaction rates on stylolitic surfaces.

AB - Compaction of sedimentary porous rock by dissolution and precipitation is a complex deformation mechanism, that is often localized on stylolites and pressure solution seams. We consider a one-dimensional model of compaction near a thin clay-rich stylolite embedded in a porous rock. Under the assumption that the clay enhances solubility, the model predicts a reactive transport away from the clay layer followed by pore cementation. The evolution of the porosity, reactant transport, and compaction rate are studied as functions of model parameters and shown to reach a stationary state. We find good agreement between the porosity distribution predicted by the model and previously reported field measurements. The model provides quantitative estimates for compaction rates on stylolitic surfaces.

U2 - 10.1029/2012JB009245

DO - 10.1029/2012JB009245

M3 - Journal article

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VL - 117

SP - B08203

JO - Journal of Geophysical Research

JF - Journal of Geophysical Research

ER -

Compaction of porous rock by dissolution on discrete stylolites: A one-dimensional model

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