Hydrogen Science and Engineering : Materials, Processes, Systems and Technology 2016
DOI: 10.1002/9783527674268.ch26
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Geologic Storage of Hydrogen – Fundamentals, Processing, and Projects

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Cited by 35 publications
(17 citation statements)
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“…In the context of the USHS system, the cyclic injection of hydrogen into (and possible retrieval from) a brine-filled permeable formation is part of multi-phase flow problems that have been studied extensively (Hashemi et al 2021;Liebscher et al 2016). In this case, a two-phase hydrogen-brine system is immiscible-the fluids are separated by a capillary interface.…”
Section: Fluid Dynamics Of Hydrogen In a Brine-saturated Porous Mediummentioning
confidence: 99%
“…In the context of the USHS system, the cyclic injection of hydrogen into (and possible retrieval from) a brine-filled permeable formation is part of multi-phase flow problems that have been studied extensively (Hashemi et al 2021;Liebscher et al 2016). In this case, a two-phase hydrogen-brine system is immiscible-the fluids are separated by a capillary interface.…”
Section: Fluid Dynamics Of Hydrogen In a Brine-saturated Porous Mediummentioning
confidence: 99%
“…When energy demand is lower than the amount of energy produced, the system operation can direct excess electrical energy to produce H 2 , which has a high energy density (Hassanpouryouzband et al, 2020). In order to establish regional or national hydrogen networks and to support the large-scale use of hydrogen, geological hydrogen storage can be a key enabler, providing the much-needed energy storage solutions at TWh scales (Liebscher et al, 2016). Geological subsurface formations not only have enormous storage capacity, but are also globally abundant, making geological storage of H 2 in porous rocks a cost-effective and efficient procedure.…”
Section: Introductionmentioning
confidence: 99%
“…We have less experience with underground hydrogen storage in porous geological formations. Practical applications are limited to storing town gas in aquifers (25-60% H 2 , 10-33% CH 4 , 12-20% CO and CO 2 and <30% N 2 ), e.g., in Beynes (France) or Lobodice (Czech Republic) [14,15]. The hydrogen-containing gas storage facilities are also located in depleted natural gas fields in Argentina (pilot project for hydrogen storage in the Diadema field) [16] and Austria (project "Underground Sun Storage" for storing gas containing 10% hydrogen) [9,17].…”
Section: Hydrogen Storagementioning
confidence: 99%