1. Arsenate(V) removal from aqueous system by using modified incinerated sewage sludge ash (ISSA) as a novel adsorbent
- Author
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Jing Nie, Hui Yin, Chi Sun Poon, Qiming Wang, Shengya Gao, and Jiang-Shan Li
- Subjects
Environmental Engineering ,Health, Toxicology and Mutagenesis ,0208 environmental biotechnology ,chemistry.chemical_element ,Incineration ,02 engineering and technology ,010501 environmental sciences ,01 natural sciences ,Water Purification ,chemistry.chemical_compound ,Adsorption ,Environmental Chemistry ,Recycling ,Arsenic ,0105 earth and related environmental sciences ,Aqueous solution ,Sewage ,Public Health, Environmental and Occupational Health ,Arsenate ,General Medicine ,General Chemistry ,Hydrogen-Ion Concentration ,Pollution ,020801 environmental engineering ,chemistry ,Wastewater ,Ionic strength ,Arsenates ,Sewage treatment ,Water Pollutants, Chemical ,Sludge ,Nuclear chemistry - Abstract
Adsorption methods have been widely used in wastewater treatment due to its high removal efficiency, easy operation and handling, economic efficiency and little secondary pollution to the environment. In this paper, a high-iron containing incineration sewage sludge ash (ISSA) was modified by combined acid leaching and precipitation processes to improve its adsorption capacity of As(V). The effects of pH, time, temperature and ionic strength on the adsorption of As(V) were investigated by batch adsorption experiments. The results indicated that iron (mainly present as hematite) in the ISSA was rearranged to Fe(SO4)OH. The modified ISSA showed an excellent adsorption potential for As(V) under acidic conditions and the adsorption capacity was around 9 times of the unmodified ISSA at pH 2–3. The adsorption process was fast during the first 2 h and reached an equilibrium at around 6 h. The Freundlich model could well fit the adsorption isotherm data, the presence of NO3− and Cl− had a negligible influence on the As(V) removal by the modified ISSA, while PO43− and SO42− could significantly suppress As(V) removal via competitive adsorption. After 3 cycles of regeneration, the modified ISSA still showed a satisfying adsorption capacity. As(V) was removed by the modified ISSA mainly through ligand exchange reaction with hydroxyl oxygen (OH-) to form inner-sphere complexes. Therefore, the modified ISSA can be a promising material for As(V) removal from wastewater in particular due to the waste recycling potential.
- Published
- 2021