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RESEARCH ARTICLE

Solar-driven advanced oxidation processes for full mineralisation of azo dyes in wastewater

Chunhong Nie A , Pingping Sun A , Lingyue Zhu A , Simeng Gao A , Hongjun Wu A and Baohui Wang A B
+ Author Affiliations
- Author Affiliations

A College of Chemistry and Chemical Engineering, Northeast Petroleum University, Daqing 163318, China.

B Corresponding author. Email: wangbh@nepu.edu.cn

Environmental Chemistry 14(3) 188-197 https://doi.org/10.1071/EN16202
Submitted: 13 December 2016  Accepted: 2 March 2017   Published: 20 March 2017

Environmental context. Full mineralisation of synthetic azo dyes in industrial wastewater is a tough job for traditional wastewater treatment technologies. There is an urgent need for the development of both sustainable and environmentally friendly technology capable of fully mineralising these azo compounds. We show that solar-driven advanced oxidation processes are capable of completely mineralising azo compounds with high utilisation of solar energy.

Abstract. Mineralisation of synthetic azo dyes in industrial wastewater is an energy-intensive process in treatment technology. The Solar Thermal Electrochemical Process for advanced oxidation processes (STEP-AOPs) utilises solar energy and electricity for the activation and electrooxidation of organic pollutants to harmless, small and non-toxic molecules with no other energy consumption. Based on molecular structure and chemistry, the STEP-AOPs for the treatment of azo dyes in wastewater, as exemplified with a typical azo dye, methyl orange, is reported for the first time. Thermodynamic calculations of the temperature-dependent potentials of methyl orange demonstrate that Gibbs free energy decreased by 161 kJ mol–1 and the potential decreased by 0.019 V with an increase of temperature from 20 to 80 °C, which indicates that the drop in both energy and potential specifically fits the STEP-AOPs technique. Experimental results showed that the STEP-AOPs achieved a total organic carbon (TOC) removal of 95.6 % for methyl orange. The TOC removal rate improved by 39.8 % and the unit TOC electricity consumption decreased by 53.8 % at 80 °C compared with conventional methods (20 °C). The mineralisation mechanism for methyl orange was a gradual shortening of the molecular chain through cleavage of the azo bond, breakdown of the benzene ring and formation of inorganic small molecules susceptible to be oxidised to non-toxic small molecules, and carbon dioxide via STEP-AOPs. The evidence shows that the STEP-AOPs is capable of mineralising azo compounds completely.

Additional keywords: electrochemistry, thermochemistry, wastewater treatment.


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