Metal-free heteroatom doping of carbon nitride for enhanced photocatalytic hydrogen peroxide production

Abstract

The photocatalytic production of hydrogen peroxide (H2O2) from water is a promising strategy for solar-to-chemical energy conversion. Herein, we investigate the effect of metal-free heteroatom doping (B, O, P, and S) on the structural, electronic, and photocatalytic properties of graphitic carbon nitride (C3N4) for H2O2 production under simulated solar irradiation. While pristine C3N4 exhibits stacked nanosheets, doping induces disorder, partial exfoliation, and changes in interlayer spacing, confirming successful heteroatom incorporation and modification of the electronic and optical properties. Photocatalytic experiments reveal that H2O2 production strongly depends on the sacrificial agent, pH, and reactive-species scavengers. All doped catalysts show enhanced activity compared to pristine C3N4, with 9.6-, 14.8-, 11.0-, and 16.4-fold increases for B-, P-, O-, and S-doped C3N4, respectively. S-doped C3N4 achieved the highest H2O2 production rate of 3022.1 μmol h-1 g-1 and an apparent quantum yield of 8.1\%, attributed to improved charge separation and optimized selectivity. Mechanistic studies indicate that oxygen activation mainly follows a two-electron (2e-) pathway driven by charge-carrier modulation and reactive oxygen species dynamics, with singlet oxygen and photogenerated holes playing a dominant role. In addition, S-doped C3N4 retained over 95\% of its activity after five cycles. These results highlight metal-free heteroatom doping as an effective strategy for sustainable photocatalytic H2O2 generation.