AUTHOR=Mura Jean , Ranchou-Peyruse Magali , Guignard Marion , Ducousso Marion , Larregieu Marie , Isaure Marie-Pierre , Le Hécho Isabelle , Hoareau Guilhem , Poulain Marie , Buruti Mateus de Souza , Chiquet Pierre , Caumette Guilhem , Petit Anélia , Cézac Pierre , Ranchou-Peyruse Anthony 

TITLE=Experimental simulation of H2 coinjection via a high-pressure reactor with natural gas in a low-salinity deep aquifer used for current underground gas storage

JOURNAL=Frontiers in Microbiology

VOLUME=15

YEAR=2024

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2024.1439866

DOI=10.3389/fmicb.2024.1439866

ISSN=1664-302X

ABSTRACT=<p>If dihydrogen (H<sub>2</sub>) becomes a major part of the energy mix, massive storage in underground gas storage (UGS), such as in deep aquifers, will be needed. The development of H<sub>2</sub> requires a growing share of H<sub>2</sub> in natural gas (and its current infrastructure), which is expected to reach approximately 2% in Europe. The impact of H<sub>2</sub> in aquifers is uncertain, mainly because its behavior is site dependent. The main concern is the consequences of its consumption by autochthonous microorganisms, which, in addition to energy loss, could lead to reservoir souring and alter the petrological properties of the aquifer. In this work, the coinjection of 2% H<sub>2</sub> in a natural gas blend in a low-salinity deep aquifer was simulated in a three-phase (aquifer rock, formation water, and natural gas/H<sub>2</sub> mix) high-pressure reactor for 3 months with autochthonous microorganisms using a protocol described in a previous study. This protocol was improved by the addition of protocol coupling experimental measures and modeling to calculate the pH and redox potential of the reactor. Modeling was performed to better analyze the experimental data. As in previous experiments, sulfate reduction was the first reaction to occur, and sulfate was quickly consumed. Then, formate production, acetogenesis, and methanogenesis occurred. Overall, H<sub>2</sub> consumption was mainly caused by methanogenesis. Contrary to previous experiments simulating H<sub>2</sub> injection in aquifers of higher salinity using the same protocol, microbial H<sub>2</sub> consumption remained limited, probably because of nutrient depletion. Although calcite dissolution and iron sulfide mineral precipitation likely occurred, no notable evolution of the rock phase was observed after the experiment. Overall, our results suggested that H<sub>2</sub> can be stable in this aquifer after an initial loss. More generally, aquifers with low salinity and especially low electron acceptor availability should be favored for H<sub>2</sub> costorage with natural gas.</p>