Impact of Heavy Metals on Denitrification of Simulated Mining Wastewaters

Gang Zou; Anna Ylinen; Francesco Di Capua; Stefano Papirio; Aino Maija Lakaniemi; Jaakko Puhakka

doi:10.4028/www.scientific.net/AMR.825.500

Paper Titles

Reduction and Complexation of Copper in a Novel Bioreduction System Developed to Recover Base Metals from Mine Process Waters
p.483

Sulfate Removal from Extremely Acidic Wastewaters Using Consortia of Acidophilic Sulfate-Reducing Bacteria
p.487

Performance Evaluation of Two Anaerobic Reactors for Removing Sulphate from Industrial Effluents
p.491

Acid Drainage and Metal Bioleaching by Redox Potencial Changes in Heavy Polluted Fluvial Sediments
p.496

Impact of Heavy Metals on Denitrification of Simulated Mining Wastewaters
p.500

Bioleaching for Extraction of Metals and Detoxification of Activated Sludges
p.504

Influences of pH Buffers on the Growth of Acidithiobacillus thiooxidans and Biodesulfurization Efficiency
p.508

Evaluation of Plant Species for Phytoremediation of a Mining Waste from Andacollo, Neuquén-Argentina
p.512

Field Scale Phytoremediation Experiments on a Former U Mining Site and Further Processing of the Plant Material
p.516

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 825Impact of Heavy Metals on Denitrification of...

Impact of Heavy Metals on Denitrification of Simulated Mining Wastewaters

Abstract:

Thespreading of nitrogenous compounds into the environment is a common challenge duringmining industries. Typical explosives used in mining are N-based compoundswhich lead to nitrogen contamination of groundwater and water bodies. In goldextraction, cyanide used as lixiviant is also another source of nitrogen pollution.The present work aims to investigate the effect of heavy metals ondenitrification using batch bioassays. Cu, Ni, Co and Fe influence ondenitrification process was studied at pH 7.0. Below the soluble concentrationof 62 mg/L, Ni did not inhibit denitrification, whereas denitrification wasrepressed at soluble Ni concentration above 62 mg/L. At 122 mg/L of soluble Ni,50% inhibition of denitrification was observed. Below soluble concentration of86 mg/L, Co exerted no inhibitory effect on nitrate removal but moderatelydecreased the denitrification rate. Cu slowed denitrification down resulting in40% of nitrate removal averagely at the soluble concentration below 1 mg/L. Onthe contrary, Fe supplementationresulted in iron oxidation and soluble Fe concentrations ranging from 0.4-1.6mg/L that stimulated denitrification. Thepresent work indicates that denitrification can tolerate heavy metals and canbe suitable for acid mine drainage remediation.

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Periodical:

Advanced Materials Research (Volume 825)

Pages:

500-503

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.825.500

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Online since:

October 2013

Authors:

Gang Zou, Anna Ylinen, Francesco Di Capua, Stefano Papirio, Aino Maija Lakaniemi, Jaakko Puhakka

Keywords:

Acid Mine Water, Denitrification, Fluidized-Bed Reactor, Metals

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