Monitoring Scheme for the Detection of Hydrogen Leakage from a Deep Underground Storage. Part 2: Physico-Chemical Impacts of Hydrogen Injection into a Shallow Chalky Aquifer

Gombert, Philippe; Lafortune, Stéphane; Pokryszka, Zbigniew; Lacroix, Elodie; Donato, Philippe de; Jozja, Nevila

doi:10.3390/app11062686

Cited by 4 publications

(1 citation statement)

References 23 publications

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“…Thus, it is unknown whether the results of this study are transferable to shallower aquifers. Recently, a short H 2 leak was simulated in a shallow unconfined aerobic chalk aquifer in France by injecting H 2 -saturated groundwater; notably, microbial consumption of H 2 was not observed in this field study due to the limited amount of dissolved H 2 added (9 g in total), a rapid transfer of the dissolved H 2 plume through the aquifer, and its significant dilution downstream of the injection well …”

Section: Introductionmentioning

confidence: 88%

Rapid Consumption of Dihydrogen Injected into a Shallow Aquifer by Ecophysiologically Different Microbes

Keller,

Lüders,

Hornbruch

et al. 2023

Environ. Sci. Technol.

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The envisaged future dihydrogen (H2) economy requires a H2 gas grid as well as large deep underground stores. However, the consequences of an unintended spread of H2 through leaky pipes, wells, or subterranean gas migrations on groundwater resources and their ecosystems are poorly understood. Therefore, we emulated a short-term leakage incident by injecting gaseous H2 into a shallow aquifer at the TestUM test site and monitored the subsequent biogeochemical processes in the groundwater system. At elevated H2 concentrations, an increase in acetate concentrations and a decrease in microbial α-diversity with a concomitant change in microbial β-diversity were observed. Additionally, microbial H2 oxidation was indicated by temporally higher abundances of taxa known for aerobic or anaerobic H2 oxidation. After H2 concentrations diminished below the detection limit, α- and β-diversity approached baseline values. In summary, the emulated H2 leakage resulted in a temporally limited change of the groundwater microbiome and associated geochemical conditions due to the intermediate growth of H2 consumers. The results confirm the general assumption that H2, being an excellent energy and electron source for many microorganisms, is quickly microbiologically consumed in the environment after a leakage.

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Section: Introductionmentioning

confidence: 88%