Synergistic coupling of H2O2 production and furoic acid synthesis over B-TiO2@COF S-scheme bifunctional photocatalyst

doi:10.1016/S1872-2067(25)64870-4

Abstract

Abstract:

Abstracr: The synergistic coupling of photocatalytic hydrogen peroxide (H₂O₂) production and green organic synthesis not only optimizes utilization of photogenerated electron-hole pairs but also circumvents kinetically sluggish water oxidation reaction. In this study, an efficient composite photocatalyst was developed through in-situ growth of irregular TpPa-Cl blocks on the surface of boron-doped TiO₂, which boasts a large specific surface area. Boron doping enhances light absorption range and inhibits recombination of charge carriers. Additionally, deep integration of porous TiO₂ with TpPa-Cl improves the contact between the reactants and the photocatalyst, extends the carrier lifetime, and provides more active sites. In the absence of a co-catalyst, the yield of H₂O₂ reached 2082.6 μmol g^-1 h^-1, with a furfuryl alcohol conversion rate of 94%. In-situ XPS and density functional theory calculations confirmed S-scheme charge transfer mechanism, which enhances carrier separation and transfer efficiency while retaining photogenerated electrons and holes with strong redox properties. Quenching experiments, electron paramagnetic resonance, and in-situ diffuse reflectance infrared Fourier transformed spectroscopy demonstrated that H₂O₂ was primarily generated via a 2-electron oxygen reduction reaction with ·O₂^- and OOH^* as intermediates. Furthermore, furfuryl alcohol was oxidized to the radical ·C₅H₅O₂ by h⁺ and subsequently converted to furfural or furoic acid through reactions with h⁺ or ·OH. This work presents a novel strategy for designing efficient composite photocatalysts for H₂O₂ production and green organic synthesis.

Key words: Photocatalytic H₂O₂ production, Porous structure, S-scheme heterojunction, Stability, Redox properties

Yandong Xu, Zihui Jing, Wenhao Su, Jiale Xu, Mingliang Wang. Synergistic coupling of H₂O₂ production and furoic acid synthesis over B-TiO₂@COF S-scheme bifunctional photocatalyst[J]. Chinese Journal of Catalysis, 2026, 80: 135-145.

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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(25)64870-4

https://www.cjcatal.com/EN/Y2026/V80/I1/135

Figures/Tables 8

Scheme 1. Synthesis process of the B-TiO2@COF composite.

Fig. 1. FTIR spectra (a,b) and XRD patterns (c) of obtained photocatalysts. (d) N2 physisorption isotherms of COF, B-TiO2, and B-TiO2@COF.

Fig. 2. TEM image (a), HRTEM image (b) and elemental mapping images (c?i) of B-TiO2@COF.

Fig. 3. (a) UV-vis DRS spectra of COF, TiO2, B-TiO2, TiO2@COF and B-TiO2@COF. (b) Band gaps of COF, TiO2, and B-TiO2. (c) Mott-Schottky plots of B-TiO2 and COF. (d) Band diagram of B-TiO2@COF.

Fig. 4. In-situ irradiated XPS spectra of N 1s (a) and Ti 2p (d) of COF, B-TiO2 and B-TiO2@COF. Work function of COF (b) and B-TiO2 (e). Averaged charge density plot (c) and charge density difference mapping (f) of COF (100)/B-TiO2 (101) interface. (g) Electron transfer mechanism of S-scheme B-TiO2@COF heterojunction.

Fig. 5. (a) Performance evaluation of H2O2 generation. (b) Formation rate constant (Kf) and decomposition rate constant (Kd) for H2O2 production. (c) Yields of H2O2, furoic acid, and furfural after 6 h reaction of COF, TiO2 and B-TiO2@COF. (d) Time concentration process of FAL, furfural (FF) and FAC in the photocatalytic FAL oxidation process of B-TiO2@COF.

Fig. 6. Photocurrent density (a), EIS spectra (b), PL spectra (c) and TRPL spectra (d) of samples.

Fig. 7. (a) Active free radical capture experiments for B-TiO2@COF. EPR signals of DMPO-·O2- (b) and DMPO-·OH (c) over COF, TiO2, B-TiO2 and B-TiO2@COF. (d) EPR signals of DMPO-·C5H5O2 over B-TiO2@COF. In-situ DRIFTS spectra of B-TiO2@COF in H2O, FAL, and O2 under dark (e) and light (f) conditions. (g) Reaction mechanism of photocatalytic H2O2 generation coupled with FAL oxidation.

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Synergistic coupling of H₂O₂ production and furoic acid synthesis over B-TiO₂@COF S-scheme bifunctional photocatalyst

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