A bio-reactive transport model for biomethanation in hydrogen underground storage sites

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A bio-reactive transport model for biomethanation in hydrogen underground storage sites. / Minougou, Jean Donald; Azizmohammadi, Siroos; Gholami, Raoof et al.
In: Greenhouse Gases: Science and Technology, Vol. ??? Stand: 30.10.2024, No. ??? Stand: 30.10.2024, 15.10.2024.

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Minougou JD, Azizmohammadi S, Gholami R, Ott H. A bio-reactive transport model for biomethanation in hydrogen underground storage sites. Greenhouse Gases: Science and Technology. 2024 Oct 15;??? Stand: 30.10.2024(??? Stand: 30.10.2024). doi: 10.1002/ghg.2307

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Minougou, Jean Donald ; Azizmohammadi, Siroos ; Gholami, Raoof et al. / A bio-reactive transport model for biomethanation in hydrogen underground storage sites. In: Greenhouse Gases: Science and Technology. 2024 ; Vol. ??? Stand: 30.10.2024, No. ??? Stand: 30.10.2024.

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@article{791bf82264f84c1da6026137ef80c379,
title = "A bio-reactive transport model for biomethanation in hydrogen underground storage sites",
abstract = "Underground biomethanation, which relies on the subsurface microbial activity to convert hydrogen and carbon dioxide into methane, is a promising approach to support carbon capture, utilization, and storage technology. The process involves injecting hydrogen with captured CO2 into depleted oil and gas reservoirs or aquifers colonized by hydrogenotrophic methanogens that can convert these two substrates into methane. Despite the attractiveness of this technology, there are still uncertainties about the efficiency of the conversion process, particularly the impact of microbial parameters. To investigate the efficiency of the hydrogen conversion process, we relied on a bio-reactive transport model that can mimic microbial growth and decay, consumption of substrates, and transport of reactants and products. It was found that the methane concentration peaks near the injection well when the hydrogen fraction is in the range of 75% to 80% of the injected gas composition. In addition, a noticeable hydrogen sulfide concentration can be produced due to sulfide ions in the brine. Using the Kozeny-Carman relation, an attempt was made to correlate microbial growth with reduced porosity and permeability. It was then revealed that substrate consumption by microbes leads to a drastic increase in the microbial population in the subsurface, which can reduce the petrophysical properties of the reservoir, especially in the near wellbore area. The results obtained from a series of parametric analyses showed that the hydrogen concentration in the injected gas, pressure, well spacing, and injection rate are some of the most important parameters contributing to the biomethanation process. ",
keywords = "bio-reactive transport, carbon capture and utilization, microbial H conversion, numerical reservoir sumulation, renewable methane, underground hydrogen storage",
author = "Minougou, {Jean Donald} and Siroos Azizmohammadi and Raoof Gholami and Holger Ott",
note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Greenhouse Gases: Science and Technology published by Society of Chemical Industry and John Wiley & Sons Ltd.",
year = "2024",
month = oct,
day = "15",
doi = "10.1002/ghg.2307",
language = "English",
volume = "??? Stand: 30.10.2024",
journal = "Greenhouse Gases: Science and Technology",
issn = "2152-3878",
publisher = "John Wiley & Sons, Gro{\ss}britannien",
number = "??? Stand: 30.10.2024",

}

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TY - JOUR

T1 - A bio-reactive transport model for biomethanation in hydrogen underground storage sites

AU - Minougou, Jean Donald

AU - Azizmohammadi, Siroos

AU - Gholami, Raoof

AU - Ott, Holger

N1 - Publisher Copyright: © 2024 The Author(s). Greenhouse Gases: Science and Technology published by Society of Chemical Industry and John Wiley & Sons Ltd.

PY - 2024/10/15

Y1 - 2024/10/15

N2 - Underground biomethanation, which relies on the subsurface microbial activity to convert hydrogen and carbon dioxide into methane, is a promising approach to support carbon capture, utilization, and storage technology. The process involves injecting hydrogen with captured CO2 into depleted oil and gas reservoirs or aquifers colonized by hydrogenotrophic methanogens that can convert these two substrates into methane. Despite the attractiveness of this technology, there are still uncertainties about the efficiency of the conversion process, particularly the impact of microbial parameters. To investigate the efficiency of the hydrogen conversion process, we relied on a bio-reactive transport model that can mimic microbial growth and decay, consumption of substrates, and transport of reactants and products. It was found that the methane concentration peaks near the injection well when the hydrogen fraction is in the range of 75% to 80% of the injected gas composition. In addition, a noticeable hydrogen sulfide concentration can be produced due to sulfide ions in the brine. Using the Kozeny-Carman relation, an attempt was made to correlate microbial growth with reduced porosity and permeability. It was then revealed that substrate consumption by microbes leads to a drastic increase in the microbial population in the subsurface, which can reduce the petrophysical properties of the reservoir, especially in the near wellbore area. The results obtained from a series of parametric analyses showed that the hydrogen concentration in the injected gas, pressure, well spacing, and injection rate are some of the most important parameters contributing to the biomethanation process.

AB - Underground biomethanation, which relies on the subsurface microbial activity to convert hydrogen and carbon dioxide into methane, is a promising approach to support carbon capture, utilization, and storage technology. The process involves injecting hydrogen with captured CO2 into depleted oil and gas reservoirs or aquifers colonized by hydrogenotrophic methanogens that can convert these two substrates into methane. Despite the attractiveness of this technology, there are still uncertainties about the efficiency of the conversion process, particularly the impact of microbial parameters. To investigate the efficiency of the hydrogen conversion process, we relied on a bio-reactive transport model that can mimic microbial growth and decay, consumption of substrates, and transport of reactants and products. It was found that the methane concentration peaks near the injection well when the hydrogen fraction is in the range of 75% to 80% of the injected gas composition. In addition, a noticeable hydrogen sulfide concentration can be produced due to sulfide ions in the brine. Using the Kozeny-Carman relation, an attempt was made to correlate microbial growth with reduced porosity and permeability. It was then revealed that substrate consumption by microbes leads to a drastic increase in the microbial population in the subsurface, which can reduce the petrophysical properties of the reservoir, especially in the near wellbore area. The results obtained from a series of parametric analyses showed that the hydrogen concentration in the injected gas, pressure, well spacing, and injection rate are some of the most important parameters contributing to the biomethanation process.

KW - bio-reactive transport

KW - carbon capture and utilization

KW - microbial H conversion

KW - numerical reservoir sumulation

KW - renewable methane

KW - underground hydrogen storage

UR - http://www.scopus.com/inward/record.url?scp=85206369013&partnerID=8YFLogxK

U2 - 10.1002/ghg.2307

DO - 10.1002/ghg.2307

M3 - Article

VL - ??? Stand: 30.10.2024

JO - Greenhouse Gases: Science and Technology

JF - Greenhouse Gases: Science and Technology

SN - 2152-3878

IS - ??? Stand: 30.10.2024

ER -