This article identifies and discusses the scientific challenges of hydrogen storage in porous media for safe and efficient large-scale energy storage to enable a global hydrogen economy.
The geological storage
of hydrogen is necessary to enable the successful
transition to a hydrogen economy and achieve net-zero emissions targets.
Comprehensive investigations must be undertaken for each storage site
to ensure their long-term suitability and functionality. As such,
the systematic infrastructure and potential risks of large-scale hydrogen
storage must be established. Herein, we conducted over 250 batch reaction
experiments with different types of reservoir sandstones under conditions
representative of the subsurface, reflecting expected time scales
for geological hydrogen storage, to investigate potential reactions
involving hydrogen. Each hydrogen experiment was paired with a hydrogen-free
control under otherwise identical conditions to ensure that any observed
reactions were due to the presence of hydrogen. The results conclusively
reveal that there is no risk of hydrogen loss or reservoir integrity
degradation due to abiotic geochemical reactions in sandstone reservoirs.
Abstract. Dissolved inorganic carbon (DIC) fluxes across the vadose zone are influenced by a complex interplay of biological, chemical and physical factors. A novel soil mesocosm system was evaluated as a tool for providing information on the mechanisms behind DIC percolation to the groundwater from unplanted soil. Carbon dioxide partial pressure (pCO2), alkalinity, soil moisture and temperature were measured with depth and time, and DIC in the percolate was quantified using a sodium hydroxide trap. Results showed good reproducibility between two replicate mesocosms. The pCO2 varied between 0.2 and 1.1%, and the alkalinity was 0.1–0.6 meq L−1. The measured cumulative effluent DIC flux over the 78-day experimental period was 185–196 mg L−1 m−2 and in the same range as estimates derived from pCO2 and alkalinity in samples extracted from the side of the mesocosm column and the drainage flux. Our results indicate that the mesocosm system is a promising tool for studying DIC percolation fluxes and other biogeochemical transport processes in unsaturated environments.
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