What does this research mean for the field?

Reaction-induced evolution of Co–N2O1 to Co–N1O2 sites in single-atom catalysts enables spin-selection-favored peroxymonosulfate activation, resulting in highly efficient, broad-spectrum pollutant degradation that significantly outperforms existing state-of-the-art catalysts. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to explore the impact of spin-state transitions on peroxymonosulfate activation in advanced oxidation processes.

June 4, 2026Open Access

Spin-selection-favored peroxymonosulfate activation on reaction-induced Co–N1O2 sites enables 1O2-biased yet radical-parallel oxidation

Key Points

This research aims to explore the impact of spin-state transitions on peroxymonosulfate activation in advanced oxidation processes.
Synthesis of Co1/C3N5 single-atom catalyst through a coordination-recrystallization strategy followed by argon pyrolysis.
Activation of Co–N2O1 sites to Co–N1O2 upon peroxymonosulfate activation to enable spin-selection-favored activation.
Evaluation of catalytic performance for oxytetracycline degradation and broad-spectrum activity towards antibiotics and dyes.
Achieved a 5.3-fold increase in the pseudo-first-order rate constant (kapp) for oxytetracycline degradation compared to pristine C3N5.
Outperformed over 30 state-of-the-art peroxymonosulfate-based catalysts in terms of pollutant degradation efficiency.
Demonstrated durability in complex matrix-rich waters and under continuous-flow operation.

Abstract

Abstract Transformations in metal coordination environments, particularly their impact on spin-state transitions, remain underexplored in peroxymonosulfate (PMS)-based advanced oxidation processes (AOPs). In this study, we synthesize a Co1/C3N5 single-atom catalyst using a coordination–recrystallization strategy followed by argon pyrolysis. The Co–N2O1 sites evolve to Co–N1O2 upon PMS activation, enabling spin-selection-favored activation and efficient pollutant degradation. The evolved site enables spin-selection-favored PMS activation that co-generates sulfate radicals (·SO4⁻) and singlet oxygen (1O2), operating in a 1O2-biased yet radical-parallel regime. Within this regime, Co1/C3N5 achieves a 5.3-fold increase in the pseudo-first-order rate constant (kapp) for oxytetracycline degradation relative to pristine C3N5 under identical conditions, and it consistently outperforms more than 30 state-of-the-art PMS-based catalysts. The catalyst further exhibits broad-spectrum activity toward structurally diverse antibiotics and dyes, while maintaining durability in matrix-rich waters and under continuous-flow operation. Overall, this work links reaction-induced single-site evolution to spin-aware oxygen transfer, providing concise design guidance for selective and robust PMS-activated AOP catalysts.

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