Superoxide-derived singlet oxygen generation via electron transfer-mediated activation of persulfate by heterogeneous biochar catalysts for naproxen degradation: Effects of aromatization degree on electron exchange capacity
- Authors
- Shin, Jaegwan; Kim, Young Mo; Rho, Hojung; Chon, Kangmin
- Issue Date
- Jan-2026
- Publisher
- Elsevier Ltd
- Keywords
- Pharmaceuticals; Electrochemical properties; Carbonaceous material-based catalysts; Peroxydisulfate; Non-radical reaction pathways; Aromatic structures
- Citation
- Bioresource Technology, v.440, pp 1 - 11
- Pages
- 11
- Indexed
- SCIE
SCOPUS
- Journal Title
- Bioresource Technology
- Volume
- 440
- Start Page
- 1
- End Page
- 11
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210656
- DOI
- 10.1016/j.biortech.2025.133490
- ISSN
- 0960-8524
1873-2976
- Abstract
- In this study, heterogeneous biochar catalysts derived from spent coffee grounds (HCBCs) and walnut shells (HWBCs) were synthesized at three pyrolysis temperatures (500 °C (HCBC500, HWBC500), 650 °C (HCBC650, HWBC650), and 800 °C (HCBC800, HWBC800)) to elucidate effects of changes in the aromatization degree determining electron exchange capacity (EEC) of heterogeneous biochar catalysts on the degradation of naproxen (NPX) via the electron transfer-mediated activation of peroxydisulfate (PDS). The greater EEC values of highly aromatic HCBCs and HWBCs produced at higher pyrolysis temperatures led to increased degradation efficiencies of NPX by the HCBCs/PDS and HWBCs/PDS systems. The HCBC800/PDS system achieved the highest degradation efficiency of NPX, at 80.9%, compared to 16.4–48.1% for other systems. These observations highlight that the EEC relying on the aromatization degree of heterogeneous biochar catalysts is a key factor governing the degradation of NPX via the electron transfer-mediated activation of PDS. In the HCBC800/PDS system, electrophilic decarboxylation induced by superoxide-derived singlet oxygen was mainly responsible for the degradation of NPX rather than hydroxyl radical-driven electrophilic hydroxylation. Moreover, the HCBC800/PDS system exhibited excellent reuse efficiency (≥73.2%) for the degradation of NPX over four consecutive cycles. Although increases in bioaccumulation potential and mutagenicity were detected for some degradation intermediates of NPX produced via the HCBC800/PDS system, most of them were less harmful to aquatic ecosystems. Therefore, HCBC800 could be a promising option as a carbonaceous material-based heterogeneous catalyst to activate PDS via the electron transfer for eliminating NPX.
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