Elsevier

Journal of Power Sources

Volume 466, 1 August 2020, 228342
Journal of Power Sources

A dual-cathode pulsed current electro-Fenton system: Improvement for H2O2 accumulation and Fe3+ reduction

https://doi.org/10.1016/j.jpowsour.2020.228342Get rights and content

Highlights

  • A dual-cathode pulsed current electro-Fenton (EF) system is proposed.

  • GDE was used for H2O2 generation and carbon felt was for Fe3+ reduction.

  • High H2O2 accumulation along with fast Fe3+ reduction was obtained.

  • Its energy consumption experienced the lowest level as 31.16 W h/mol H2O2.

Abstract

In conventional electro-Fenton (EF), high H2O2 accumulation and Fe3+ reduction rate are difficult to synchronously achieve on a single cathode. Then a dual-cathode pulsed current EF (DCP-EF) is proposed, where different current density imposes on gas diffusion cathode (GDE) and carbon felt (CF) alternately. In this system, GDE is mainly for H2O2 accumulation, while CF is primarily for Fe3+ reduction. Optimal current density on GDE for H2O2 formation is 10 mA cm−2, while it is 2.5 mA cm−2 for Fe3+ reduction on CF. A switching time of 20 s is alternatively utilized on each cathode. In the DCP-EF process, H2O2 accumulation witnesses a 10% improvement along with a low-level energy consumption (31.16 W h/mol H2O2) compared to the conventional one. Aside from H2O2 improvement, a higher Fe3+ reduction rate (93.8%) is also observed than the conventional one with single CF system (71%), while total iron remains stable since iron precipitation near-cathode vicinity is alleviated in DCP-EF. A 98.5% sulfamerazine decay coupled with 85.6% mineralization confirms the superiority of the proposed system. Because a higher concentration •OH is detected than that of conventional one. In conclusion, the DCP-EF system is promising, coordinating H2O2 accumulation and Fe3+ reduction simultaneously.

Keywords

Electro-Fenton
Dual cathode
Pulsed current
Sulfamerazine
Oxygen mass transfer

Cited by (0)

1

Fengxia DENG and Sixing Li contribute equally to this work.

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