UC Berkeley

Although steady progress has been achieved toward upcycling waste CO2 through diverse catalytic strategies, each approach has distinct limitations, hampering the generation of complex products like sugars. Here, we provide a roadmap that evaluates the feasibility associated with state-of-the-art electrochemical processes eligible for converting CO2 into glycolaldehydes and formaldehydes, both essential components for sugar generation through the formose reaction. We establish that even in low concentrations, glycolaldehyde plays a crucial role as an autocatalytic initiator during sugar formation and identify formaldehyde production as a bottleneck. Our study demonstrates the chemical resilience of the formose reaction successfully carried out in the chemically complex CO2 electrolysis product stream. This work reveals that CO2-initiated sugars constitute an adequate feedstock for fast-growing and genetically modifiable Escherichia coli. Altogether, we introduce a roadmap, supported by experimental evidence, that pushes the boundaries of product complexity achievable from CO2 electroconversion while integrating CO2 into life-sustaining sugars.