Joel Haber1,John Gregoire1,Yungchieh Lai1,Lan Zhou1,Kevin Kan1,Nicholas Watkins1,Jonas Peters1,Theodor Agapie1,Christopher Muzzillo2,Andriy Zakutayev2
California Institute of Technology1,National Renewable Energy Laboratory2
Joel Haber1,John Gregoire1,Yungchieh Lai1,Lan Zhou1,Kevin Kan1,Nicholas Watkins1,Jonas Peters1,Theodor Agapie1,Christopher Muzzillo2,Andriy Zakutayev2
California Institute of Technology1,National Renewable Energy Laboratory2
Direct solar-driven conversion of carbon dioxide to chemicals and fuels requires identification of efficient, durable, and selective photocathodes. Chalcogenide p-type semiconductors, exemplified by chalcopyrite Cu(In,Ga)Se<sub>2</sub> (CIGS), have been effectively deployed as photocathodes. However, selectivity toward CO<sub>2</sub> reduction and durability of the commonly used CdS buffer layer remain unsolved challenges. We have demonstrated that for the wide band gap CuGa<sub>3</sub>Se<sub>5</sub> chalcopyrite absorber these challenges are well addressed by an organic coating generated in situ from an N,N′-(1,4-phenylene)bispyridinium ditriflate salt in the electrolyte. The molecular additive provides a 30-fold increase in selectivity toward CO2R products compared to the unmodified system and lowers Cd corrosion at least 10-fold. This dual functionality highlights the promise of hybrid solid-state-molecular photocathodes for enabling durable and efficient solar fuel systems. This presentation will highlight the variations in product selectivity and durability observed for different combinations of coatings derived from molecular precursors in the electrolyte with photocathodes including CuGa<sub>3</sub>Se<sub>5</sub> and Cu(In,Ga)Se<sub>2</sub>, with and without CdS buffer layers.