Iron oxide-based adsorbents offer strong potential for hydrogen sulfide (H2S) removal due to their cost-effectiveness and environmental compatibility. However, how to precisely control multiscale microstructural features that govern adsorption performance remains inadequately understood. Here, a pH-controlled hydrothermal synthesis strategy using ferrous sulfate heptahydrate as the iron precursor was developed to elucidate the relationship between the microstructure and the adsorption performance of Fe-based adsorbents. A distinct functional pH threshold (≥7) was identified, above which a pure-phase Fe3O4 was formed and the surface Fe2+/Fe3+ redox couple became stabilized/activated, enabling effective H2S capture. H2S fixed-bed tests were conducted at ambient temperature with an inlet concentration of 1000 ppm. The adsorbent synthesized at pH = 13. 0 integrated mixed-valence Fe2+/Fe3+ sites, defect-rich surfaces with enhanced basicity, mesoporosity, and exposed 111 facets, delivering a breakthrough capacity of 85 mg/g (H2S outlet concentration 2S capture and provides a design strategy for tuning redox-active sites, defects, and surface basicity.
Li et al. (Mon,) studied this question.
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