Deciphering the Quantitative Relationship Between the Photocatalytic Activity and the Built-In Electric Field of Heterojunction

Abstract

The principle of heterojunction in physics has been extensively referenced in heterogeneous photocatalysis, but it appears to have been utilized qualitatively more as a concept than as a method. The reason is that the quantitative correlation between the intensity of the built-in electric field (BIEF) and photocatalytic activity has not been established, primarily due to the challenges in directly measuring the BIEF of nanosized photocatalysts. To address this, both powder-type and single-crystal-type SiC@WO3-x-T heterostructures are prepared to quantitatively investigate the dependence of photocatalytic CO2 reduction activities on BIEF intensity. A strong linear correlation between the effective photoelectron number (NEPN) for CO2 reduction and the BIEF intensity is revealed for the first time. Specifically, NEPN increases by 0.25 μmol g−1 when Vbi (built-in potential) increases by 1 kV for the powder sample. In contrast, for the single-crystal sample, NEPN rises by 0.16 μmol with a 1 kV cm−1 increase in Ebi (built-in electric field). This study not only bridges a critical gap in heterojunction photocatalysis research but also demonstrates a method to amplify the built-in electric field by engineering the interface species, thereby enhancing the photocatalytic performance. 1.