Selective scission of glucose molecule by a Pd-modulated Co-based catalyst for efficient CO2 reduction under mild conditions.

Pd–induced electron–migration of Co promotes C–C bond cleavage of glucose for selective production of active intermediate and hydrogen transfer, achieving CO 2 reduction efficiency 12.6–fold of the catalyst–free case. [Display omitted] Combining terrestrial biomass as the reductant with submarine-type hydrothermal environments for CO 2 reduction represents a possible approach for novel energy production systems that sustainably circulate carbon. However, increasing the reductive power of biomass is the main limitation of this potential method. Herein, we demonstrate that Co-doped with small amounts of Pd enhances the reduction of CO 2 by selectively producing an active intermediate from carbohydrates. This catalytic reaction utilized glucose as a reductant to achieve high formate production efficiency (458.6 g kg−1) with nearly 100% selectivity with 7.5 wt% Pd 1 Co 20 / γ –Al 2 O 3 at a moderate temperature of 225 °C. The regulation of the electronic structure of the catalytic Co surface by the dopant Pd plays a key role in promoting the C–C bond cleavage of glucose and hydrogen transfer for CO 2 reduction. The findings presented here indicate that biomass can serve as the hydrogen source for CO 2 reduction and provide insight into the potential utilization of CO 2 in sustainable industrial applications. [ABSTRACT FROM AUTHOR]