6533b861fe1ef96bd12c509a

RESEARCH PRODUCT

Microscopic Revelation of Charge-Trapping Sites in Polymeric Carbon Nitrides for Enhanced Photocatalytic Activity by Correlating with Chemical and Electronic Structures

Jih-jen WuDipak B. NimbalkarDipak B. NimbalkarMonika StaśSheng Shu HouShyue Chu Ke

subject

021110 strategic defence & security studiesMaterials sciencePhotoluminescenceHeptazineHydrogen bond0211 other engineering and technologiesDFT calculation02 engineering and technologyElectronPhotoelectric effect021001 nanoscience & nanotechnologyPhotochemistrylaw.inventionpolymeric carbon nitridechemistry.chemical_compoundchemistrylawSSNMR spectroscopyPhotocatalysisGeneral Materials ScienceDensity functional theoryvisible-light-driven photocatalyst0210 nano-technologyElectron paramagnetic resonanceEPR spectroscopy

description

The influences of chemical and electronic structures on the photophysical properties of polymeric carbon nitrides (PCNs) photocatalysts, which govern the microscopic mechanisms of the superior photocatalytic activity under visible-light irradiation, have been resolved in this work. Time-resolved photoluminescence and in situ electron paramagnetic resonance measurements indicate that the photoexcited electrons in the fractured PCNs swiftly transfer to the C2p-localized states where the trapped photoelectrons exhibit longer lifetime compared to those in the ordinary PCNs. Moreover, the structure deviation at the carbon (Cb) atoms around the bridging sites of heptazine ring units, where trapped photoelectrons are localized, has been determined in the fractured PCNs based on the 13C solid-state nuclear magnetic resonance spectra and the density functional theory calculations. Accordingly, the formation of fractured PCNs by breaking the in-plane hydrogen bonds at a high temperature is a promising strategy for the enhancement of photocatalytic activity.

yearjournalcountryeditionlanguage
2019-05-07ACS Applied Materials & Interfaces
https://doi.org/10.1021/acsami.9b02494