Efficient photocatalytic water decontamination over a wide pH range by C and O co-doped carbon nitride with tunable band structure

The metal-free, non-toxic, and highly tunable structure of carbon nitride confers unique advantages in photocatalytic advanced oxidation processes. Regulating the generation of radical and non-radical species during photocatalysis to maintain high degradation efficiency across different water matrices is of great practical significance for the application of carbon nitride. In this study, a C and O co-doped modified carbon nitride (UCN) with a high specific surface area was developed for efficient photodegradation of p-chlorophenol (p-Cl) without exogenous oxidants. Characterizations demonstrated that UCN in higher specific surface area exposed more active sites. Additionally, with rising doping levels, UCN exhibited enhanced light absorption capability and a narrower bandgap, which favored the separation of photogenerated electron-hole pairs. The primary active species were identified as holes, accompanied by the generation of superoxide radicals (center dot O-2(-)) and singlet oxygen (O-1(2)) depending on the pH value. Under acidic conditions, O-1(2) was predominantly generated, whereas center dot O-2(-) dominated under alkaline conditions. As a result, the removal efficiency of p-Cl was enhanced under both strongly acidic and alkaline conditions. The pseudo-first-order rate constants for p-Cl removal at pH 3, 7, and 11 were 0.0558, 0.0354, and 0.0443 min(-1), respectively. Moreover, combining DFT calculations and LC-MS data, analysis on the intermediate products of p-Cl degradation revealed unique characteristics at different pH values, further proving the flexible tunability and providing insights into the practical application of modified carbon nitride.