Novel CaO–SiO<sub>2</sub> Sorbent and Bifunctional Ni/Co–CaO/SiO<sub>2</sub> Complex for Selective H<sub>2</sub> Synthesis from Cellulose

Abstract

Catalysis- and sorption-enhanced biomass gasification is a promising route to high-purity hydrogen (H<sub>2</sub>); however, most CaO-based sorbents for CO<sub>2</sub> capture have poor surface area and mechanical properties, lose carrying capacity over multiple uses, and have insufficient porosity to accommodate extra catalyst sites. We aimed to develop a high-surface-area CaO–SiO<sub>2</sub> framework onto which catalysts could be grafted. The best CaO–SiO<sub>2</sub> sorbent (<i>n</i><sub>Ca</sub>/<i>n</i><sub>Si</sub> = 2:1) maintained a CaO conversion of 65% even after 50 carbonation–decarbonation cycles, better than commercial micrometer-sized CaO or tailored CaO, because of stabilization via Ca–O–Si interactions and an ordered porous structure. Bimetallic catalyst grains (Ni/Co alloy, <20 nm) could be evenly loaded onto this structure by impregnation. The resulting bifunctional complex produced H<sub>2</sub> at nearly the same rate as a mixture of catalyst and commercial CaO while using less total sorbent/catalyst. Furthermore, this complex was much more durable due to its higher coking resistance and stable structure. After 25 carbonation–decarbonation cycles, the new catalyst–sorbent complex enhanced the H<sub>2</sub> yield from cellulose far more than a mixture of catalyst and commercial CaO did following the same treatment

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