posted on 2022-03-15, 13:34authored byXian Shi, Xing’an Dong, Ye He, Ping Yan, Shihan Zhang, Fan Dong
CO2 photoreduction currently faces two challenges: low
photoreduction efficiency and poor product selectivity. Ultrathin
two-dimensional bismuth oxyhalide, with a large number of surface
vacancies (active sites), is an ideal material for regulating CO2 photoconversion. However, surface vacancies in this catalyst
are easily deactivated during the reaction. CO2 photoreduction
relies on sufficient active sites; hence, we synthesized ultrathin
Bi4O5Cl2 nanoplates via a water-assisted
self-assembly process with sufficient photoswitchable surface Cl vacancies
for solar-driven CO2-to-CO reduction. The surface Cl vacancies
were generated under light irradiation and filled again with migrated
Cl– under an O2 atmosphere after turning
off the irradiation. These photoswitchable vacancies enabled Bi4O5Cl2 to produce 58.49 μmol g–1 CO after 4 h of irradiation with high stability and
lowered the energy barriers of the rate-determining (CO2-to-COOH–) and selectivity-determining steps (COOH–-to-CO), enabling 100% product selectivity. The reversible,
photoswitchable Cl vacancies have a higher potential as active sites
for CO2 photoreduction than synthetically introduced static
surface vacancies, which could provide a feasible strategy for the
creation of highly dynamic, active-defective catalysts for solar-energy
conversion.