Research Article
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Year 2020, Volume: 38 Issue: 4, 1781 - 1790, 05.10.2021

Abstract

References

  • [1] Randall CW., Buth D., (1984) Nitrite build up in activated sludge resulting from temperature effects, Water Pollution Control Federation 56(9), 1039-1044.
  • [2] Aslan Ş.,(2017) Single and combined effects of copper and nickel on nitrification organisms in batch units, European Journal of Sustainable Development Research 2(1), 51-56.
  • [3] Yeung CH., Francis CA., (2013) Adaptation of nitrifying microbial biomass to nickel in batch incubations, Appl Microbiol Biotechnol 97, 847-857.
  • [4] Beg SA., Hassan MM., Chaudhry MAS.,(1998) Chromium(VI) inhibition in multi-substrate carbon oxidation and nitrification process in a upflow packed bed biofilm reactor, Biochemical Engineering Journal 1(2),143-152.
  • [5] Lee YW., Ong SK., Sato C., (1997) Effects of Heavy Metals on Nitrifying Bacteria, Wat.Sci.Tech 36(12), 69-74.
  • [6] Young B., Delatolla R., Kennedy K., Laflamme E., Stintzi A., (2017) Low temperatureMBBR nitrification: microbiome analysis, Water Res. 111, 224–233
  • [7] Zhang M., Yu M., Wang Y., He C., Pang J., Wu J., (2019) Operational optimization of a three-stage nitrification moving bed biofilm reactor(NMBBR) by obtaining enriched nitrifying bacteria:Nitrifying performance, microbial community, and kinetic parameters, Science of the Total Environment 697(134101).
  • [8] Çeçen F., Semerci N., Geyik AG., (2009) Inhibitory effects of Cu,Zn, Ni and Co on nitrification and relevance of speciation, Chemical Technology and Biotechnology 85(4), 520-528.
  • [9] Wang X.H., Gai LH., Sun XF., Xie H.J., Gao MM., Wang SG.,(2010) Effects of long term addition of Cu(II) and Ni(II) on the biochemical properties of aerobic granules in sequencing batch reactors, Applied Microbiology and Biotechnology 86, 1967-1975.
  • [10] Bhat SA., Cui G., Li W., Wei Y., Li F., (2020) Effect of heavy metals on the performance and bacterial profiles of activated sludge in a semi-continuous reactor, Chemosphere 125035,1-8.
  • [11] Salles F.J., Toledo MCB., Cesar ACG., Ferreira GM., Barberio A., (2016) Cytotoxic and genotoxic assessment of surface water from S~ao Paulo State, Brazil,during the rainy and dry seasons, Ecotoxicology 25, 633-645.
  • [12] Sato C., Schnoor JL and Mc Donald DB., (1986) Characterization of effects of copper, cadmium and nickel on growth Nitrosomonas europaea, Environmental Toxicology Chemistry 1, 357-376.
  • [13] Liu X., Chowdhury MMI., Zaman M., Kim M., Nakhla G., (2019) Acute and chronic toxicity of nickel to nitrifiers at different temperatures, Journal of Environmental Sciences 82, 169-178.
  • [14] Kapoor V., Li X., Elk M., Chandran K., Impellitteri CA., Santo Domingo JW.,(2015) Impact of heavy metals on transcriptional and physiological activity of nitrifying bacteria, Environ. Sci.Technol 49, 13454–13462.
  • [15] Yin K., Lv M., Wang Q., Wu Y., Liao C., Zhang W., (2016) Simultaneous bioremediation and biodetection of mercury ion through surface display of carboxylesterase E2 from Pseudomonas aeruginosa PA1, Water Res. 103, 383–390.
  • [16] Bagby MM., Sherrard JH., (1981) Combined effects of cadmium and nickel on the activated sludge process, Water Pollution Control Federation 53(11), 1609-1619.
  • [17] Harper SC., Manoharan R., Mavinic DS., Randall CW., (1996) Chromium and nickel toxicity during the biotraetment of high ammonia landfill leachate, Water Environment Research 68(1), 19-24.
  • [18] Aslan Ş., Gurbuz B.,(2011) Influence of operational parameters and low nickel concentrations on partial nitrification in a submerged biofilter, Applied Biochem Biotechnol 165, 1543-1555.
  • [19] Skinner FA., Walker N., (1961) Growth of nitrosomanas in batch and continuous culture, Arch. Microbiol 38, 339-349.
  • [20] Sujarittanonta S., Sherrard JH., (1981) Activated sludge nickel toxicity studies, J Water Pollution Control Federation 53, 1314–1322.
  • [21] Gikas P., (2008) Single and combined effects of nickel (Ni(II)) and cobalt (Co(II)) ions on activated sludge and on other aerobic microorganisms: a review, Journal of Hazardous Matererial 159(2-3),187–200.
  • [22] Ray D., Benkaraache S., Lemay JF., Landry D., Drogui P., Tyagi RD., (2019). High strength ammonium wastewater treatment by MBR: Steady state nitrification kinetic parameters, Journal of Water Process Engineering 32(100945).
  • [23] Semerci N., Çeçen F., (2009) Effect of continuous Cd feeding on the performance of a nitrification reactor, Biodegradation 20, 155-164.
  • [24] Hall ER., Murphy KL., (1985) Sludge age and substrate effects on nitrification kinetics, Water Pollution Control Federation 57(5), 413-418.
  • [25] Hocaoğlu SM., Insel G., Çokgör EU., Orhon D., (2011) Effect of sludge age on simultaneous nitrification and denitrification in membrane bioreactor, Bioresource Technology 102(12), 6665-6672.
  • [26] Grundıtz C., Dalhammar G., (2001) Development of nitrification inhibition assays using püre cultures of nitrosomonas and nitrobacter, Water Research 35(2), 433-440.
  • [27] Dinçer AR., Kargı F., (2000) Kinetics of sequential nitrification and denitrification processes, Enzyme and Microbial Technology 27, 37-42.
  • [28] Liu R., Li S., Yu N., Zhao C., Gao X., Gao C., (2020) Performance evaluation and microbial community shift of sequencing batch reactors under different nickel concentrations, Environmental Technology and Innovation, 19(100991).
  • [29] Dinçer AR., Kargı F.,(1999) Salt inhibition of nitrification and denitrification in saline wastewater, Environmental Technology 20, 1147-1153.
  • [30] Qiao Z., Sun R., Wu Y., Hu S., Liu X., Chan J., Mi X., (2020) Characteristics and metabolic pathway of bacteria for hetetrophic nitrification and aerobic denitrification in aquatic ecosytems, Environmental Research 191(110069).

MATHEMATICAL MODELLING AND DETERMINATION OF THE NICKEL INHIBITION CONSTANT FOR NITRIFICATION

Year 2020, Volume: 38 Issue: 4, 1781 - 1790, 05.10.2021

Abstract

Conversion of ammonia into nitrate is sensitive to a number of inhibitors. There is limited information on the nitrification inhibition coefficient and mathematical models in the current literature. The nickel inhibition constant was found in nitrogen removal using an activated sludge system. In the first set of experiments, nickel-free wastewater was used to determine the optimum operating conditions. In the second set of experiments, the effect of the nickel concentration on the system performance was investigated. The ammonium removal efficiency was not affected by low Ni concentrations (< 7mg/L). When the Ni concentration was increased to 11 mg/L, the nitrification efficiency decreased by more than 45.53%.
Based on the experimental results, a mathematical model was developed, and the nickel inhibition constants (KNi) were found to be 8.75 mg/L.

References

  • [1] Randall CW., Buth D., (1984) Nitrite build up in activated sludge resulting from temperature effects, Water Pollution Control Federation 56(9), 1039-1044.
  • [2] Aslan Ş.,(2017) Single and combined effects of copper and nickel on nitrification organisms in batch units, European Journal of Sustainable Development Research 2(1), 51-56.
  • [3] Yeung CH., Francis CA., (2013) Adaptation of nitrifying microbial biomass to nickel in batch incubations, Appl Microbiol Biotechnol 97, 847-857.
  • [4] Beg SA., Hassan MM., Chaudhry MAS.,(1998) Chromium(VI) inhibition in multi-substrate carbon oxidation and nitrification process in a upflow packed bed biofilm reactor, Biochemical Engineering Journal 1(2),143-152.
  • [5] Lee YW., Ong SK., Sato C., (1997) Effects of Heavy Metals on Nitrifying Bacteria, Wat.Sci.Tech 36(12), 69-74.
  • [6] Young B., Delatolla R., Kennedy K., Laflamme E., Stintzi A., (2017) Low temperatureMBBR nitrification: microbiome analysis, Water Res. 111, 224–233
  • [7] Zhang M., Yu M., Wang Y., He C., Pang J., Wu J., (2019) Operational optimization of a three-stage nitrification moving bed biofilm reactor(NMBBR) by obtaining enriched nitrifying bacteria:Nitrifying performance, microbial community, and kinetic parameters, Science of the Total Environment 697(134101).
  • [8] Çeçen F., Semerci N., Geyik AG., (2009) Inhibitory effects of Cu,Zn, Ni and Co on nitrification and relevance of speciation, Chemical Technology and Biotechnology 85(4), 520-528.
  • [9] Wang X.H., Gai LH., Sun XF., Xie H.J., Gao MM., Wang SG.,(2010) Effects of long term addition of Cu(II) and Ni(II) on the biochemical properties of aerobic granules in sequencing batch reactors, Applied Microbiology and Biotechnology 86, 1967-1975.
  • [10] Bhat SA., Cui G., Li W., Wei Y., Li F., (2020) Effect of heavy metals on the performance and bacterial profiles of activated sludge in a semi-continuous reactor, Chemosphere 125035,1-8.
  • [11] Salles F.J., Toledo MCB., Cesar ACG., Ferreira GM., Barberio A., (2016) Cytotoxic and genotoxic assessment of surface water from S~ao Paulo State, Brazil,during the rainy and dry seasons, Ecotoxicology 25, 633-645.
  • [12] Sato C., Schnoor JL and Mc Donald DB., (1986) Characterization of effects of copper, cadmium and nickel on growth Nitrosomonas europaea, Environmental Toxicology Chemistry 1, 357-376.
  • [13] Liu X., Chowdhury MMI., Zaman M., Kim M., Nakhla G., (2019) Acute and chronic toxicity of nickel to nitrifiers at different temperatures, Journal of Environmental Sciences 82, 169-178.
  • [14] Kapoor V., Li X., Elk M., Chandran K., Impellitteri CA., Santo Domingo JW.,(2015) Impact of heavy metals on transcriptional and physiological activity of nitrifying bacteria, Environ. Sci.Technol 49, 13454–13462.
  • [15] Yin K., Lv M., Wang Q., Wu Y., Liao C., Zhang W., (2016) Simultaneous bioremediation and biodetection of mercury ion through surface display of carboxylesterase E2 from Pseudomonas aeruginosa PA1, Water Res. 103, 383–390.
  • [16] Bagby MM., Sherrard JH., (1981) Combined effects of cadmium and nickel on the activated sludge process, Water Pollution Control Federation 53(11), 1609-1619.
  • [17] Harper SC., Manoharan R., Mavinic DS., Randall CW., (1996) Chromium and nickel toxicity during the biotraetment of high ammonia landfill leachate, Water Environment Research 68(1), 19-24.
  • [18] Aslan Ş., Gurbuz B.,(2011) Influence of operational parameters and low nickel concentrations on partial nitrification in a submerged biofilter, Applied Biochem Biotechnol 165, 1543-1555.
  • [19] Skinner FA., Walker N., (1961) Growth of nitrosomanas in batch and continuous culture, Arch. Microbiol 38, 339-349.
  • [20] Sujarittanonta S., Sherrard JH., (1981) Activated sludge nickel toxicity studies, J Water Pollution Control Federation 53, 1314–1322.
  • [21] Gikas P., (2008) Single and combined effects of nickel (Ni(II)) and cobalt (Co(II)) ions on activated sludge and on other aerobic microorganisms: a review, Journal of Hazardous Matererial 159(2-3),187–200.
  • [22] Ray D., Benkaraache S., Lemay JF., Landry D., Drogui P., Tyagi RD., (2019). High strength ammonium wastewater treatment by MBR: Steady state nitrification kinetic parameters, Journal of Water Process Engineering 32(100945).
  • [23] Semerci N., Çeçen F., (2009) Effect of continuous Cd feeding on the performance of a nitrification reactor, Biodegradation 20, 155-164.
  • [24] Hall ER., Murphy KL., (1985) Sludge age and substrate effects on nitrification kinetics, Water Pollution Control Federation 57(5), 413-418.
  • [25] Hocaoğlu SM., Insel G., Çokgör EU., Orhon D., (2011) Effect of sludge age on simultaneous nitrification and denitrification in membrane bioreactor, Bioresource Technology 102(12), 6665-6672.
  • [26] Grundıtz C., Dalhammar G., (2001) Development of nitrification inhibition assays using püre cultures of nitrosomonas and nitrobacter, Water Research 35(2), 433-440.
  • [27] Dinçer AR., Kargı F., (2000) Kinetics of sequential nitrification and denitrification processes, Enzyme and Microbial Technology 27, 37-42.
  • [28] Liu R., Li S., Yu N., Zhao C., Gao X., Gao C., (2020) Performance evaluation and microbial community shift of sequencing batch reactors under different nickel concentrations, Environmental Technology and Innovation, 19(100991).
  • [29] Dinçer AR., Kargı F.,(1999) Salt inhibition of nitrification and denitrification in saline wastewater, Environmental Technology 20, 1147-1153.
  • [30] Qiao Z., Sun R., Wu Y., Hu S., Liu X., Chan J., Mi X., (2020) Characteristics and metabolic pathway of bacteria for hetetrophic nitrification and aerobic denitrification in aquatic ecosytems, Environmental Research 191(110069).
There are 30 citations in total.

Details

Primary Language English
Journal Section Research Articles
Authors

Ali Rıza Dincer This is me 0000-0002-9294-0643

Publication Date October 5, 2021
Submission Date June 19, 2020
Published in Issue Year 2020 Volume: 38 Issue: 4

Cite

Vancouver Dincer AR. MATHEMATICAL MODELLING AND DETERMINATION OF THE NICKEL INHIBITION CONSTANT FOR NITRIFICATION. SIGMA. 2021;38(4):1781-90.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK https://eds.yildiz.edu.tr/sigma/