Effect of Alkalinity Type and Concentration on Nitrifying Biofilm Activity

Biesterfeld, Sidney; Farmer, Greg; Russell, Phil; Figueroa, Linda

doi:10.2175/106143003x140971

Cited by 50 publications

(21 citation statements)

References 18 publications

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“…In the present work, the initial pH values were included in this range, which were always more than 6.5 and less than 8.9, and no nitrification inhibition could be highlighted, as we did not observe a postponed nitrification start in relation to the lower values of pH. Similar observations could be reported for alkalinity, which has been widely reported to affect the nitrification process [64,65]. Alkalinity is an important parameter, as it influences pH and is a measure of the inorganic carbon available for nitrifiers; a lack of alkalinity will stop nitrification.…”

Section: Discussionsupporting

confidence: 86%

Ammonium Transformation in 14 Lakes along a Trophic Gradient

Leoni

Patelli

Soler

et al. 2018

Water

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Ammonia is a widespread pollutant in aquatic ecosystems originating directly and indirectly from human activities, which can strongly affect the structure and functioning of the aquatic foodweb. The biological oxidation of NH 4 + to nitrite, and then nitrate is a key part of the complex nitrogen cycle and a fundamental process in aquatic environments, having a profound influence on ecosystem stability and functionality. Environmental studies have shown that our current knowledge of physical and chemical factors that control this process and the abundance and function of involved microorganisms are not entirely understood. In this paper, the efficiency and the transformation velocity of ammonium into oxidised compounds in 14 south-alpine lakes in northern Italy, with a similar origin, but different trophic levels, are compared with lab-scale experimentations (20 • C, dark, oxygen saturation) that are performed in artificial microcosms (4 L). The water samples were collected in different months to highlight the possible effect of seasonality on the development of the ammonium oxidation process. In four-liter microcosms, concentrations were increased by 1 mg/L NH 4 + and the process of ammonium oxidation was constantly monitored. The time elapsed for the decrease of 25% and 95% of the initial ion ammonium concentration and the rate for that ammonium oxidation were evaluated. Principal Component Analysis and General Linear Model, performed on 56 observations and several chemical and physical parameters, highlighted the important roles of total phosphorus and nitrogen concentrations on the commencement of the oxidation process. Meanwhile, the natural concentration of ammonium influenced the rate of nitrification (µg NH 4 + /L day). Seasonality did not seem to significantly affect the ammonium transformation. The results highlight the different vulnerabilities of lakes with different trophic statuses.

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Section: Discussionsupporting

confidence: 86%

Ammonium Transformation in 14 Lakes along a Trophic Gradient

Leoni

Patelli

Soler

et al. 2018

Water

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“…The dissolved oxygen (DO) in the effluent never dropped below 7.6 mg L -1 in any experiments, and the pH ranged from 7.3 to 7.4. Alkalinity in the water was sufficiently high (5.5 meq L -1 as HCO 3 ), and therefore was not a limiting factor in nitrification (Biesterfeld et al, 2003).…”

Section: Ammonium Load Shift Experimentsmentioning

confidence: 99%

Effects of dynamic operating conditions on nitrification in biological rapid sand filters for drinking water treatment

Lee

Boe-Hansen²,

Musovic

et al. 2014

Water Research

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“…The alkalinity results were lower than 30 mg/L in all sampling scenarios; the recommendation for fish cultivation to avoid pH variations is 25-100 mg/L [26]. Alkalinities between 40-80 mg/L are beneficial in nitrification processes [27].…”

Section: Resultsmentioning

confidence: 99%

Effluents from Fish Farming Ponds: A View from the Perspective of Its Main Components

et al. 2017

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Among the animal protein production activities, world aquaculture has the highest growth rate, and is mainly practiced in ground-excavated ponds. However, with great productivity comes the concern about the increasing generation of effluents, mainly at the moment of fish removal, when high loads of organic matter and nutrients are released into the environment. Thus, this study evaluated the quality of effluents through the principal component analysis (PCA) in samples from nurseries of different sizes in four sampling scenarios. Analysis was performed during the process of fish removal in Nile Tilapia intensive fish farming sites at various properties in the Western region of Paraná State in Brazil. Twenty physical and chemical parameters were analyzed in each effluent sample using standard methods of effluent analysis. The results indicated that the concentrations of Suspended Solids (SS), Total Solids (TS), Chemical Oxygen Demand (COD), and Total Phosphorus (TP) increased significantly at the end of the fish removal process, which caused a progressive deterioration in the effluent released into the environment. Hence, regulating water management during cultivation, as well as mitigating the effects of effluent generated in fish removal, is indispensable to maintain the legality, profitability, and sustainability of this sector.

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Effect of Alkalinity Type and Concentration on Nitrifying Biofilm Activity

Cited by 50 publications

References 18 publications

Ammonium Transformation in 14 Lakes along a Trophic Gradient

Ammonium Transformation in 14 Lakes along a Trophic Gradient

Effects of dynamic operating conditions on nitrification in biological rapid sand filters for drinking water treatment

Effluents from Fish Farming Ponds: A View from the Perspective of Its Main Components

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