Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment

The depth of the sulfate-methane transition (SMT) above gas hydrate systems is a direct proxy to interpret upward methane flux and hydrate saturation. However, two competing reaction pathways can potentially form the SMT. Moreover, the pore water profiles across the SMT in shallow sediment show broa...

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Bibliographic Details
Main Author: Chatterjee, Sayantan
Other Authors: Hirasaki, George J., Chapman, Walter G., Zygourakis, Kyriacos, Dickens, Gerald R., Dugan, Brandon
Format: Thesis
Language:English
Published: 2012
Subjects:
Gas hydrate
Marine sediment
Continental slopes
Focused fluid flow
Lithologic heterogeneity
Local fluid flux
Sulfate-methane transition
Anaerobic oxidation of methane
Organoclastic sulfate reduction
Numerical modeling
Methane hydrate
Online Access:https://hdl.handle.net/1911/64663
id ftriceuniv:oai:scholarship.rice.edu:1911/64663
record_format openpolar
spelling ftriceuniv:oai:scholarship.rice.edu:1911/64663 2023-05-15T17:12:12+02:00 Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment Chatterjee, Sayantan Hirasaki, George J. Chapman, Walter G. Zygourakis, Kyriacos Dickens, Gerald R. Dugan, Brandon 2012-09-06T04:17:20Z application/pdf https://hdl.handle.net/1911/64663 eng eng Chatterjee, Sayantan. "Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment." (2012) Diss., Rice University. https://hdl.handle.net/1911/64663 . https://hdl.handle.net/1911/64663 123456789/ETD-2012-05-126 Gas hydrate Marine sediment Continental slopes Focused fluid flow Lithologic heterogeneity Local fluid flux Sulfate-methane transition Anaerobic oxidation of methane Organoclastic sulfate reduction Numerical modeling Thesis Text 2012 ftriceuniv 2022-08-09T20:31:03Z The depth of the sulfate-methane transition (SMT) above gas hydrate systems is a direct proxy to interpret upward methane flux and hydrate saturation. However, two competing reaction pathways can potentially form the SMT. Moreover, the pore water profiles across the SMT in shallow sediment show broad variability leading to different interpretations for how carbon, including CH4, cycles within gas-charged sediment sequences over time. The amount and distribution of marine gas hydrate impacts the chemistry of several other dissolved pore water species such as the dissolved inorganic carbon (DIC). A one-dimensional (1-D) numerical model is developed to account for downhole changes in pore water constituents, and transient and steady-state profiles are generated for three distinct hydrate settings. The model explains how an upward flux of CH4 consumes most SO42- at a shallow SMT implying that anaerobic oxidation of methane (AOM) is the dominant SO42- reduction pathway, and how a large flux of 13C-enriched DIC enters the SMT from depth impacting chemical changes across the SMT. Crucially, neither the concentration nor the d13C of DIC can be used to interpret the chemical reaction causing the SMT. The overall thesis objective is to develop generalized models building on this 1-D framework to understand the primary controls on gas hydrate occurrence. Existing 1-D models can provide first-order insights on hydrate occurrence, but do not capture the complexity and heterogeneity observed in natural gas hydrate systems. In this study, a two-dimensional (2-D) model is developed to simulate multiphase flow through porous media to account for heterogeneous lithologic structures (e.g., fractures, sand layers) and to show how focused fluid flow within these structures governs local hydrate accumulation. These simulations emphasize the importance of local, vertical, fluid flux on local hydrate accumulation and distribution. Through analysis of the fluid fluxes in 2-D systems, it is shown that a local Peclet number characterizes ... Thesis Methane hydrate Rice University: Digital Scholarship Archive
institution Open Polar
collection Rice University: Digital Scholarship Archive
op_collection_id ftriceuniv
language English
topic Gas hydrate
Marine sediment
Continental slopes
Focused fluid flow
Lithologic heterogeneity
Local fluid flux
Sulfate-methane transition
Anaerobic oxidation of methane
Organoclastic sulfate reduction
Numerical modeling
spellingShingle Gas hydrate
Marine sediment
Continental slopes
Focused fluid flow
Lithologic heterogeneity
Local fluid flux
Sulfate-methane transition
Anaerobic oxidation of methane
Organoclastic sulfate reduction
Numerical modeling
Chatterjee, Sayantan
Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
topic_facet Gas hydrate
Marine sediment
Continental slopes
Focused fluid flow
Lithologic heterogeneity
Local fluid flux
Sulfate-methane transition
Anaerobic oxidation of methane
Organoclastic sulfate reduction
Numerical modeling
description The depth of the sulfate-methane transition (SMT) above gas hydrate systems is a direct proxy to interpret upward methane flux and hydrate saturation. However, two competing reaction pathways can potentially form the SMT. Moreover, the pore water profiles across the SMT in shallow sediment show broad variability leading to different interpretations for how carbon, including CH4, cycles within gas-charged sediment sequences over time. The amount and distribution of marine gas hydrate impacts the chemistry of several other dissolved pore water species such as the dissolved inorganic carbon (DIC). A one-dimensional (1-D) numerical model is developed to account for downhole changes in pore water constituents, and transient and steady-state profiles are generated for three distinct hydrate settings. The model explains how an upward flux of CH4 consumes most SO42- at a shallow SMT implying that anaerobic oxidation of methane (AOM) is the dominant SO42- reduction pathway, and how a large flux of 13C-enriched DIC enters the SMT from depth impacting chemical changes across the SMT. Crucially, neither the concentration nor the d13C of DIC can be used to interpret the chemical reaction causing the SMT. The overall thesis objective is to develop generalized models building on this 1-D framework to understand the primary controls on gas hydrate occurrence. Existing 1-D models can provide first-order insights on hydrate occurrence, but do not capture the complexity and heterogeneity observed in natural gas hydrate systems. In this study, a two-dimensional (2-D) model is developed to simulate multiphase flow through porous media to account for heterogeneous lithologic structures (e.g., fractures, sand layers) and to show how focused fluid flow within these structures governs local hydrate accumulation. These simulations emphasize the importance of local, vertical, fluid flux on local hydrate accumulation and distribution. Through analysis of the fluid fluxes in 2-D systems, it is shown that a local Peclet number characterizes ...
author2 Hirasaki, George J.
Chapman, Walter G.
Zygourakis, Kyriacos
Dickens, Gerald R.
Dugan, Brandon
format Thesis
author Chatterjee, Sayantan
author_facet Chatterjee, Sayantan
author_sort Chatterjee, Sayantan
title Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
title_short Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
title_full Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
title_fullStr Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
title_full_unstemmed Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment
title_sort modeling fluid flow effects on shallow pore water chemistry and methane hydrate distribution in heterogeneous marine sediment
publishDate 2012
url https://hdl.handle.net/1911/64663
genre Methane hydrate
genre_facet Methane hydrate
op_relation Chatterjee, Sayantan. "Modeling Fluid Flow Effects on Shallow Pore Water Chemistry and Methane Hydrate Distribution in Heterogeneous Marine Sediment." (2012) Diss., Rice University. https://hdl.handle.net/1911/64663 .
https://hdl.handle.net/1911/64663
123456789/ETD-2012-05-126
_version_ 1766068987462942720

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