Chapter-8: Physiochemical parametric considerations for optimal underground hydrogen storage

Nawal Noshad; Shwetank Krishna; Gerhard Thonhauser; Syahrir Ridha; Suhaib Umer  Ilyas

Chapter-8: Physiochemical parametric considerations for optimal underground hydrogen storage

Nawal Noshad, Shwetank Krishna, Gerhard Thonhauser, Syahrir Ridha, Suhaib Umer Ilyas

Chair of Drilling and Completion Engineering (590)

Research output: Chapter in Book/Report/Conference proceeding › Chapter › Research

Abstract

Underground hydrogen storage (UHS) is a recent technology and a solution to large-scale hydrogen storage that can be utilized as an energy source to meet future energy demands. Hydrogen can be stored in subsurface formations such as salt caverns, aquifers, and depleted hydrocarbon reservoirs. The type of reservoir rock, the fluid it contains, that is, most often brine (saline water), its properties, and its interactions all have essential implications for the behavior of hydrogen in deep reservoir conditions. Studying the effects of these physiochemical properties is essential as it can help to determine several other aspects of UHS, such as storage capacity, performance, containment security, safe injection and withdrawal operations, etc. While these parameters are interrelated, this chapter is focused on and categorized into solid-based properties, fluid-based properties, and solid-fluid interactions. Each of these factors play a vital role in proper evaluation of UHS and its operations to ensure the feasibility of the process.

Original language	English
Title of host publication	Subsurface Hydrogen Energy Storage
Publisher	Elsevier
Publication status	Published - 2025

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Cite this

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abstract = "Underground hydrogen storage (UHS) is a recent technology and a solution to large-scale hydrogen storage that can be utilized as an energy source to meet future energy demands. Hydrogen can be stored in subsurface formations such as salt caverns, aquifers, and depleted hydrocarbon reservoirs. The type of reservoir rock, the fluid it contains, that is, most often brine (saline water), its properties, and its interactions all have essential implications for the behavior of hydrogen in deep reservoir conditions. Studying the effects of these physiochemical properties is essential as it can help to determine several other aspects of UHS, such as storage capacity, performance, containment security, safe injection and withdrawal operations, etc. While these parameters are interrelated, this chapter is focused on and categorized into solid-based properties, fluid-based properties, and solid-fluid interactions. Each of these factors play a vital role in proper evaluation of UHS and its operations to ensure the feasibility of the process.",

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T1 - Chapter-8: Physiochemical parametric considerations for optimal underground hydrogen storage

AU - Noshad, Nawal

AU - Krishna, Shwetank

AU - Thonhauser, Gerhard

AU - Ridha, Syahrir

AU - Ilyas, Suhaib Umer

PY - 2025

Y1 - 2025

N2 - Underground hydrogen storage (UHS) is a recent technology and a solution to large-scale hydrogen storage that can be utilized as an energy source to meet future energy demands. Hydrogen can be stored in subsurface formations such as salt caverns, aquifers, and depleted hydrocarbon reservoirs. The type of reservoir rock, the fluid it contains, that is, most often brine (saline water), its properties, and its interactions all have essential implications for the behavior of hydrogen in deep reservoir conditions. Studying the effects of these physiochemical properties is essential as it can help to determine several other aspects of UHS, such as storage capacity, performance, containment security, safe injection and withdrawal operations, etc. While these parameters are interrelated, this chapter is focused on and categorized into solid-based properties, fluid-based properties, and solid-fluid interactions. Each of these factors play a vital role in proper evaluation of UHS and its operations to ensure the feasibility of the process.

AB - Underground hydrogen storage (UHS) is a recent technology and a solution to large-scale hydrogen storage that can be utilized as an energy source to meet future energy demands. Hydrogen can be stored in subsurface formations such as salt caverns, aquifers, and depleted hydrocarbon reservoirs. The type of reservoir rock, the fluid it contains, that is, most often brine (saline water), its properties, and its interactions all have essential implications for the behavior of hydrogen in deep reservoir conditions. Studying the effects of these physiochemical properties is essential as it can help to determine several other aspects of UHS, such as storage capacity, performance, containment security, safe injection and withdrawal operations, etc. While these parameters are interrelated, this chapter is focused on and categorized into solid-based properties, fluid-based properties, and solid-fluid interactions. Each of these factors play a vital role in proper evaluation of UHS and its operations to ensure the feasibility of the process.

M3 - Chapter

BT - Subsurface Hydrogen Energy Storage

PB - Elsevier

ER -