The hydrothermal alteration of olivine [(Mg,Fe)₂SiO₄] has attracted considerable attention as it represents not only a potential way to produce hydrogen (H₂) by the oxidation of Fe(II) in it, but also to store CO₂ by its carbonation. The combination of the strategies of H₂ production and CO₂ storage during H₂O-olivine-CO₂ reaction may be a promising way to contribute to low-carbon society development. During H₂O-olivine-CO₂ reaction, the olivine grain size is a key parameter in controlling olivine dissolution and products generation rates.

In this study, three experiments with olivine particles of 28-53, 53-90 and 90-160 µm were conducted in 0.5 mol/L NaHCO₃ solution at 300 °C for 72 h. Olivine alteration rate (r, wt%/h) was closely related to its geometric surface area (GS, m²/g), with the linear relationship of r=4.097GS. H₂ production was much higher with the simultaneous CO₂ storage [in magnesite, (Mg,Fe)CO₃] in the experiment with an olivine grain size of 28-53 µm than those with larger olivine grain sizes. The highest cumulative H₂ yield was 118 mmol/kg_olivine in 72 h. The inhibited magnesite precipitation in experiments with olivine grain size >53 µm was attributed to the low Mg concentrations caused by the slow olivine dissolutions. The results also suggest olivine serpentinization proceeded faster than carbonation, and the covering of olivine with serpentines [(Mg,Fe)₃Si₂O₅(OH)₄] may inhibited further olivine alteration and H₂ production.
Therefore, decrease the olivine grain size to < 53 µm is an efficient way not only to enhance olivine alteration with H₂ production but also to realize simultaneous H₂ production and CO₂ storage during H₂O-olivine-CO₂ reaction.