Serpentinization of peridotite (mainly includes olivine and pyroxene) usually produces molecular H₂, which may potentially contribute to today’s always-increasing energy demands. On the other hand, peridotite also appears to be a good candidate for CO₂ sequestration by mineralization. Based on this, our previous research has successfully combined the strategies of H₂ production and CO₂ mineralization by olivine alteration in CO₂-rich hydrothermal system. However, olivine may not necessarily act as a peridotite equivalent during alteration, and the pyroxene influence is still poorly understood.
In this study, we examined the reactions in H₂O-olivine/pyroxene-CO₂ systems by performing hydrothermal experiments in 0.5 mol/L NaHCO₃ solutions under conditions of 300 ^oC and 10 MPa. The results show that H₂ was produced when olivine and/or pyroxene reacted in NaHCO₃ solution, and the presence of pyroxene in starting material suppressed H₂ production from per kg of mineral. Pyroxene was converted solely to serpentine, rather than brucite and magnesite even in CO₂-contained solutions, which indicates CO₂ mineralization was only realized in olivine-contained systems. In addition, the pyroxene serpentinization process is quicker than olivine. In the experiment with olivine/pyroxene weight ratio of 3/2, all of the pyroxene was altered after 72 h reaction, whereas half of the olivine particles have remained. Based on experimental results, we propose that the presence of pyroxene in starting material will suppress the H₂ production and CO₂ storage during peridotite alteration; however, the inhibition effect will be decreased along the reaction time.