Biological removal of ammonia and nitrate from simulated mine and mill effluents

Koren, David W.; Gould, W. Douglas; Bédard, Pierre

doi:10.1016/s0304-386x(99)00088-2

Cited by 70 publications

(32 citation statements)

References 27 publications

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“…If over-discharged, NO 3 À favors the eutrophication of receiving waters [4] and increases the risk of severe diseases such as methemoglobinemia [5]. Chemolithotrophic denitrification has recently gained increasing interest.…”

Section: Introductionmentioning

confidence: 99%

Chemolithotrophic denitrification in biofilm reactors

Capua

Papirio

Lens

et al. 2015

Chemical Engineering Journal

163

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Section: Introductionmentioning

confidence: 99%

Chemolithotrophic denitrification in biofilm reactors

Capua

Papirio

Lens

et al. 2015

Chemical Engineering Journal

163

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“…Kasia et al [6] used an aerobic continuously stirred tank reactor for nitrification followed by upflow gravel packed column for denitrification applied to a wastewater generated by a metal refining company. They have obtained high ammonia removal efficiencies (up to 89%), but the nitrate removal (maximum 15% removal efficiency) did not meet the expectations previously projected by Koren et al [2] using synthetic wastewater. The failure of denitrification was explained on the basis of the used carbon source, a sewage that contained a variety of unknown substances including surfactants that could have inhibited the biological process.…”

Section: Introductionmentioning

confidence: 36%

“…In the last decade, studies on biological nitrogen removal using synthetic wastewater to simulate industrial discharges have been performed in order to evaluate the potential application of the nitrification-denitrification process to industrial wastewaters [2], but few studies focused on real industrial wastewater have been published in the metal-processing industry. Schuch et al [3] and Buchhesiter et al [4] wastewater streams from a metal working industry, obtaining that released ammonia from ethanolamines of the permeate in the denitrification stage could only be nitrified during aerobic treatment if it was co-treated together with a non-toxic wastewater stream from other sources in the factory.…”

Section: Introductionmentioning

confidence: 99%

Biological nitrate removal from wastewater of a metal-finishing industry

Gabaldón

Izquierdo

Martínez‐Soria

et al. 2007

Journal of Hazardous Materials

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“…Elevated concentrations of phosphorus (P) in the mine effluent are mainly due to dissolution of apatite in apatite iron ore, chemicals used in the flotation process and sewage sludge used for mine waste remediation (Hansson 2006;Häyrynen et al 2008). Due to the role of nitrogen and phosphorus as nutrients, discharge of nutrient-rich mine water may result in eutrophication, with increased growth, changed species composition of phytoplankton and macrophytes, and oxygen deficiency in the receiving waters (Koren et al 2000;Mattila et al 2007;Galloway et al 2008). To mitigate the problem of eutrophication, it is of interest to find a suitable technique for the removal of these excess nutrients.…”

Section: Introductionmentioning

confidence: 99%

Nitrogen uptake and cycling in Phragmites australis in a lake-receiving nutrient-rich mine water: a 15N tracer study

2015

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Uptake and cycling of nitrogen (N) in the littoral zone of a lake-receiving nutrient-rich mine water located in Boliden, northern Sweden, was investigated. Stable isotope tracer solutions of 15 N as NH 4? (NAM mesocosm) or NO 3 -(NOX mesocosm) were added to mesocosms enclosing plants of common reed (Phragmites australis). The 15 N abundance in various plant parts was measured at pre-defined time intervals over an experimental period of 22 days. During the course of the experiment, plant parts from the NAM mesocosms were significantly more enriched in 15 N than plant parts from the NOX mesocosms. On day 13, Dd 15 N values of the fine roots from the NAM mesocosms had reached ?8220 %, while the maximum Dd 15 N value in NOX roots was considerably lower at ?4430 %. Using 15 N values in macrophyte tissues present at the end of the experiment enabled calculations of uptake rates and % of tracer N recovered in the plant (%tracerNrecov). Maximum tracer uptake rates were higher for the NAM mesocosms (1.4 lg g -1 min -1 or 48 mg N m -2 d -1 ) compared to the NOX mesocosms (0.23 lg g -1 min -1 or 8.5 mg N m -2 d -1 ). Calculations of %tracerNrecov indicated that 1-8 and 25-44 % of added N was assimilated by plants in the NOX and NAM mesocosms, respectively. Hence, P. australis was more effective in assimilating NH 4 ? , and a larger portion of the tracer N accumulated in the roots compared to the other plant parts. Consequently, macrophyte N removal is most effective for cold-climate aquatic systems receiving mine water dominated by NH 4? . For permanent removal of N, the whole plant (including the roots) should be harvested.

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Biological removal of ammonia and nitrate from simulated mine and mill effluents

Cited by 70 publications

References 27 publications

Chemolithotrophic denitrification in biofilm reactors

Chemolithotrophic denitrification in biofilm reactors

Biological nitrate removal from wastewater of a metal-finishing industry

Nitrogen uptake and cycling in Phragmites australis in a lake-receiving nutrient-rich mine water: a 15N tracer study

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