Absolute adsorption of light hydrocarbons and carbon dioxide in shale rock and isolated kerogen

Natural gas production from shale formations has changed the energy landscape. Knowledge of adsorption in the subsurface shale formations improves resource assessment. The excess adsorption is directly measurable from experiments. Evaluation of fluid content in shale is based on the absolute adsorpt...

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Published inFuel (Guildford) Vol. 235; pp. 855 - 867
Main Authors Wu, Tianhao, Zhao, Huangjing, Tesson, Stéphane, Firoozabadi, Abbas
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.01.2019
Elsevier BV
Elsevier
Subjects
Absolute adsorption
Adsorption
Carbon dioxide
Chemical compounds
Chemical Sciences
Computational Engineering, Finance, and Science
Computer Science
Ethane
Gas production
Gravimetric method
Gravimetry
High pressure
Hydrocarbons
Kerogen
Natural gas
Oil and gas production
or physical chemistry
Pressure
Rocks
Shale
Shale gas
Shales
Theoretical and
Gravimetric method
Kerogen
Shale gas
Absolute adsorption
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Abstract Natural gas production from shale formations has changed the energy landscape. Knowledge of adsorption in the subsurface shale formations improves resource assessment. The excess adsorption is directly measurable from experiments. Evaluation of fluid content in shale is based on the absolute adsorption. At high pressure relevant to subsurface conditions, the computation of absolute adsorption from excess adsorption has shortcomings when the conventional models are used. In this work, we first present the excess sorption data of light hydrocarbons and carbon dioxide in subsurface shale rock and in isolated kerogen. Gravimetric method was used in our measurements. The results show that, at high pressure, the excess adsorption of ethane and carbon dioxide decreases significantly as pressure increases. Excess adsorption of ethane at 60 °C for the shale sample investigated becomes negative at high pressure. The conventional models may provide a non-monotonic absolute adsorption and even magnify the unphysical negative adsorption. In addition to the proposed model based on adsorbed layer volume, we also account for effective sample volume due to the pore volume accessibility by different molecules, as well as the swelling of kerogen. The adsorption data from subsurface shale and the method for analysis presented in this work set the stage for prediction capability in hydrocarbon production from shale reservoirs.
AbstractList Natural gas production from shale formations has changed the energy landscape. Knowledge of adsorption in the subsurface shale formations improves resource assessment. The excess adsorption is directly measurable from experiments. Evaluation of fluid content in shale is based on the absolute adsorption. At high pressure relevant to subsurface conditions, the computation of absolute adsorption from excess adsorption has shortcomings when the conventional models are used. In this work, we first present the excess sorption data of light hydrocarbons and carbon dioxide in subsurface shale rock and in isolated kerogen. Gravimetric method was used in our measurements. The results show that, at high pressure, the excess adsorption of ethane and carbon dioxide decreases significantly as pressure increases. Excess adsorption of ethane at 60 °C for the shale sample investigated becomes negative at high pressure. The conventional models may provide a non-monotonic absolute adsorption and even magnify the unphysical negative adsorption. In addition to the proposed model based on adsorbed layer volume, we also account for effective sample volume due to the pore volume accessibility by different molecules, as well as the swelling of kerogen. The adsorption data from subsurface shale and the method for analysis presented in this work set the stage for prediction capability in hydrocarbon production from shale reservoirs.
Author Tesson, Stéphane
Zhao, Huangjing
Firoozabadi, Abbas
Wu, Tianhao
Author_xml – sequence: 1
  givenname: Tianhao
  orcidid: 0000-0002-4749-6707
  surname: Wu
  fullname: Wu, Tianhao
  organization: Reservoir Engineering Research Institute, 595 Lytton Avenue Suite B, Palo Alto, CA 94301, USA
– sequence: 2
  givenname: Huangjing
  surname: Zhao
  fullname: Zhao, Huangjing
  organization: Reservoir Engineering Research Institute, 595 Lytton Avenue Suite B, Palo Alto, CA 94301, USA
– sequence: 3
  givenname: Stéphane
  surname: Tesson
  fullname: Tesson, Stéphane
  organization: Reservoir Engineering Research Institute, 595 Lytton Avenue Suite B, Palo Alto, CA 94301, USA
– sequence: 4
  givenname: Abbas
  surname: Firoozabadi
  fullname: Firoozabadi, Abbas
  email: af@rerinst.org
  organization: Reservoir Engineering Research Institute, 595 Lytton Avenue Suite B, Palo Alto, CA 94301, USA
BackLink https://hal.science/hal-01952077$$DView record in HAL
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Keywords Gravimetric method
Kerogen
Shale gas
Absolute adsorption
Language English
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Snippet Natural gas production from shale formations has changed the energy landscape. Knowledge of adsorption in the subsurface shale formations improves resource...
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SubjectTerms Absolute adsorption
Adsorption
Carbon dioxide
Chemical compounds
Chemical Sciences
Computational Engineering, Finance, and Science
Computer Science
Ethane
Gas production
Gravimetric method
Gravimetry
High pressure
Hydrocarbons
Kerogen
Natural gas
Oil and gas production
or physical chemistry
Pressure
Rocks
Shale
Shale gas
Shales
Theoretical and
Title Absolute adsorption of light hydrocarbons and carbon dioxide in shale rock and isolated kerogen
URI https://dx.doi.org/10.1016/j.fuel.2018.08.023
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https://hal.science/hal-01952077
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