Enhancement of E-Peroxone process with waste-tire carbon composite cathode for tinidazole degradation

Enhancement of E-Peroxone process with waste-tire carbon composite cathode for tinidazole degradation

The cathode is the key component in the electro-peroxone process (E-Peroxone), which is popularly constructed with carbon materials. This study developed an innovative method to fabricate a cathode with waste-tire carbon (WTC) whose performance was evaluated for the degradation of tinidazole (TNZ),...

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Veröffentlicht in:Water science and technology 2022-06, Vol.85 (12), p.3357-3369
Hauptverfasser: Xu, Anlin, Liu, Wanqun, Chu, Leping, Zhang, Yunhai, He, Yide, Zhang, Yongjun
Format: Artikel
Sprache:eng
Schlagworte:
aop
Black carbon
Carbon
Carbon black
Cathodes
Chemical oxygen demand
Chlorine
Current density
Current efficiency
Degradation
Efficiency
Electrodes
Electrolytes
emerging organic contaminants
Gas flow
Hydrogen peroxide
Oxidation
ozonation
Ozone
perchlorate
Potassium
recalcitrant
Sodium
Tinidazole
Titanium
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Zusammenfassung:The cathode is the key component in the electro-peroxone process (E-Peroxone), which is popularly constructed with carbon materials. This study developed an innovative method to fabricate a cathode with waste-tire carbon (WTC) whose performance was evaluated for the degradation of tinidazole (TNZ), an antibiotic frequently detected in water. It was found that the addition of WTC in the cathode can significantly promote the yield of H2O2 and the current efficiency: around 2.7 times that of commercial carbon black at the same loading. The critical influencing factors were studied, including the current density, ozone concentration, initial pH value, chlorine ions and initial TNZ concentration. The scavenger tests demonstrated the possible involvement of •OH and . Some transformation products of TNZ were identified with UPLC-MS and the degradation pathway was proposed accordingly. These results demonstrated the potential of WTC for developing E-Peroxone cathodes.
ISSN:0273-1223
1996-9732
DOI:10.2166/wst.2022.178