Oxygen microprofiles within the sediment-water interface studied by optode and its implication for aeration of polluted urban rivers

Liu, Bo; Han, Ruizhi; Wang, Wenlin; Yao, Hong; Zhou, Feng

doi:10.1007/s11356-017-8631-3

Cited by 6 publications

(1 citation statement)

References 47 publications

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“…In addition, the large amounts of sediments in such rivers require efficient disposition, which is realized through resourceful utilization. At present, the main technology for river sediment treatment includes on-site and off-site technologies, such as artificial aeration [ 12 ], coagulation [ 13 ], bioremediation [ 14 ] and dredging of sediment landfills [ 15 ], dehydration after dredging [ 16 ] and sediment pyrolysis after dehydration [ 17 ]. However, the on-site technologies are unsuitable for large-scale malodorous rivers.…”

Section: Introductionmentioning

confidence: 99%

Evaluation and mechanism of ammonia nitrogen removal using sediments from a malodorous river

2018

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Malodorous rivers are among the major environmental problems of cities in developing countries. In addition to the unpleasant smell, the sediments of such rivers can act as a sink for pollutants. The excessive amount of ammonia nitrogen (NH3−N) in rivers is the main factor that causes the malodour. Therefore, a suitable method is necessary for sediment disposition and NH3−N removal in malodorous rivers. The sediment in a malodorous river (PS) in Beijing, China was selected and modified via calcination (PS-D), Na+ doping (PS-Na) and calcination–Na+ doping (PS-DNa). The NH3−N removal efficiency using the four sediment materials was evaluated, and results indicated that the NH3−N removal efficiency using the modified sediment materials could reach over 60%. PS-DNa achieved the highest NH3−N removal efficiency (90.04%). The kinetics study showed that the pseudo-second-order model could effectively describe the sorption kinetics and that the exterior activated site had the main function of P sorption. The results of the sorption isotherms indicated that the maximum sorption capacities of PS-Na, PS-D and PS-DNa were 0.343, 0.831 and 1.113 mg g−1, respectively, and a high temperature was favourable to sorption. The calculated thermodynamic parameters suggested that sorption was a feasible or spontaneous (ΔG < 0), entropy-driven (ΔS > 0), and endothermic (ΔH > 0) reaction.

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