Ferrate(<scp>VI</scp>) green oxidant: electrochemical generation, self‐decomposition, and application for reactive red 195 azo dye treatment

Nguyen, Thi Van Anh; Mai, Thi Thanh Thuy; Phan, Thi Binh; Tran, Huu Quang; Bui, Minh Quy

doi:10.1002/jctb.7734

J of Chemical Tech & Biotech

2024

DOI: 10.1002/jctb.7734

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Ferrate(VI) green oxidant: electrochemical generation, self‐decomposition, and application for reactive red 195 azo dye treatment

Thi Van Anh Nguyen,

Thi Thanh Thuy Mai,

Thi Binh Phan

et al.

Abstract: BACKGROUNDFerrate(VI), an environmentally friendly oxidant, has recently emerged as one of the most promising chemicals for water and wastewater treatment due to its versatile application as an oxidant, coagulant, and disinfectant. In this paper, the factors affecting the electrosynthesis process of ferrate using ductile iron anode were studied. Besides, the obtained ferrate was used to remove reactive red 195 (RR195).RESULTSThe optimal ferrate electrochemical synthesis conditions were determined, including 14… Show more

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Toward Continuous Electrochemical Synthesis of Ferrate

Kupec,

Plischka,

Duman

et al. 2024

Advanced Sustainable Systems

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Ferrate (Fe(VI)) is of great interest in energy storage solutions, organic synthesis, and wastewater treatment due to its decent oxidation potential and non‐toxic end‐product formation, making it a green oxidizer. The electrochemical generation of ferrate in NaOH at current densities of j ≥ 100 mA cm−2 is presented using low‐cost sacrificial iron anodes, mild steel, and spheroidal graphite cast iron (ductile iron). Under optimized reaction parameters with 40 wt.% (14 m) NaOH and a ZrO2‐based diaphragm, spheroidal graphite cast iron shows no signs of passivation in 5 h experiments even at j = 150 mA cm−2. The results are used in a novel electrolysis cell with a combined geometric anode surface area of 230 cm2, incorporated in a mini‐plant suitable for continuous synthesis. This setup produces a peak ferrate concentration of 10.1 g L−1 (84 mm) after 5 h in 1.6 L anolyte volume, resulting in a total ferrate mass of 16.2 g. Optimal electrolysis temperatures are between 35 and 50 °C. The highest current efficiency is 63.0%, and the lowest specific energy consumption is 9.2 kWh kg−1 ferrate. The presented work is an essential step toward the continuous electrochemical synthesis of ferrate using sacrificial anodes under basic conditions.

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Toward Continuous Electrochemical Synthesis of Ferrate

Kupec,

Plischka,

Duman

et al. 2024

Advanced Sustainable Systems

View full text Add to dashboard Cite

show abstract

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Ferrate(VI) green oxidant: electrochemical generation, self‐decomposition, and application for reactive red 195 azo dye treatment

Cited by 1 publication

References 73 publications

Toward Continuous Electrochemical Synthesis of Ferrate

Toward Continuous Electrochemical Synthesis of Ferrate

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