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- Title
Effects of different scrap iron as anode in Fe-C micro-electrolysis system for textile wastewater degradation.
- Authors
Sun, Zhenhua; Xu, Zhihua; Zhou, Yuwei; Zhang, Daofang; Chen, Weifang
- Abstract
The degradation of organic contaminants in actual textile wastewater was carried out by iron carbon (Fe-C) micro-electrolysis. Different Fe-C micro-electrolysis systems (SIPA and SISA) were established by using scrap iron particle (SIP) and scrap iron shaving (SIS) as anode materials. The optimal condition of both systems was obtained at the initial pH of 3.0, dosage of 30 g/L and Fe/C mass ratio of 1:1. Commercial spherical Fe-C micro-electrolysis material (SFC) was used for comparison under the same condition. The results indicated that total organic carbon (TOC) and chroma removal efficiencies of SIPA and SISA were superior to that of SFC. Total iron concentration in solution and XRD analysis of electrode materials revealed that the former showed relatively high iron corrosion intensity and the physicochemical properties of scrap iron indeed affected the treatment capability. The UV-vis and 3DEEM analysis suggested that the pollutants degradation was mainly attributed to the combination of reduction and oxidation. Furthermore, the potential degradation pathways of actual textile wastewater were illustrated through the GC-MS analysis. Massive dyes, aliphatic acids, and textile auxiliaries were effectively degraded, and the SIPA and SISA exhibited higher performance on the degradation of benzene ring and dechlorination than that by SFC. In addition, SIPA and SISA exhibited high stability and excellent reusability at low cost.
- Subjects
DEGRADATION of textiles; IRON; IRON corrosion; TEXTILE chemicals; ANODES; DYE-sensitized solar cells
- Publication
Environmental Science & Pollution Research, 2019, Vol 26, Issue 26, p26869
- ISSN
0944-1344
- Publication type
Article
- DOI
10.1007/s11356-019-05931-3