Adverse Effects of Ammonia on Nitrification Process: the Case of Chinese Shallow Freshwater Lakes

Chen, Guoyuan; Cao, Xiuyun; Song, Changchun; Zhou, Yiyong

doi:10.1007/s11270-009-0253-z

Cited by 24 publications

(8 citation statements)

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“…Controls on nitrification in such lakes may also include: levels of connectivity between sediment microbes, N pools, and water column oxygen sources; exposure to excess light (French et al ), ammonium (Chen et al ), acidity (Jeschke et al ), or anthropogenic pollutants such as metals or pharmaceuticals (Kraigher and Mandic‐Mulec ; Rosi‐Marshall and Royer ); competition for ammonium or nitrite by heterotrophic microbes or algae (Agbeti and Smol ), which may be elevated in lakes with high sediment‐water contact or primary productivity. In unpolluted freshwaters, nitrite is thought to occur at trace concentrations and nitrite oxidation is not commonly viewed as a rate‐limiting step of nitrification, although nitrite may sometimes accumulate to toxic concentrations in agricultural streams or groundwater (Stanley and Maxted ; Chen et al ). While these factors can influence spatio‐temporal variability in gross or net N transformation rates, understanding of total winter production of nitrate and ammonium could be enhanced through ecosystem‐level studies that employ long‐term winter data.…”

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confidence: 99%

Ice duration drives winter nitrate accumulation in north temperate lakes

Powers

Labou

Baulch

et al. 2017

Limnol Oceanogr Letters

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The duration of winter ice cover on lakes varies substantially with climate variability, and has decreased over the last several decades in many temperate lakes. However, little is known of how changes in seasonal ice cover may affect biogeochemical processes under ice. We examined winter nitrogen (N) dynamics under ice using a 301 yr dataset from five oligotrophic/mesotrophic north temperate lakes to determine how changes in inorganic N species varied with ice duration. Nitrate accumulated during winter and was strongly related to the number of days since ice-on. Exogenous inputs accounted for less than 3% of nitrate accumulation in four of the five lakes, suggesting a paramount role of . Given that winters with shorter ice duration (< 120 d) have become more frequent in these lakes since the late 1990s, peak winter nitrate concentrations and cumulative nitrate production under ice may be declining. As ice extent and duration change, the physical and chemical conditions supporting life will shift. This research suggests we may expect changes in the form and amount of inorganic N, and altered dissolved nitrogen : phosphorus ratios, in lakes during winters with shorter ice duration.*Correspondence: steve.powers@wsu.edu Author Contribution Statement: SMP led the manuscript effort. SMP and EHS came up with the research questions and designed the study approach. SMP, SEH, and SGL contributed to statistical analyses. SMP and SGL contributed figures. EHS, NRL, and RJH contributed data. SMP, EHS, HMB, NRL, and SEH interpreted results. All authors contributed to writing of the paper.Data Availability Statement: Data are available in the North Temperate Lakes LTER repository at https://lter.limnology.wisc.edu/data. We used a merged winter data set of (1) This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. Scientific Significance StatementMany freshwater lakes freeze during winter, yet little is known about the rates and controls on ecological processes under ice, such as nitrification, or how these processes may be affected by ongoing and future changes in ice cover. To address these knowledge gaps, we analyzed three decades of winter chemistry data related to the nitrogen cycle in five seasonally ice-covered north temperate lakes. We found that nitrate accumulated during winter as a result of internal lake processes and was strongly related to the number of days since ice-on. Consequently, winters with shorter ice duration may result in reduced total nitrification and lower peak nitrate concentrations, with potentially important implications for annual lake biogeochemical budgets, primary productivity, and biological communities.

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confidence: 99%

Ice duration drives winter nitrate accumulation in north temperate lakes

Powers

Labou

Baulch

et al. 2017

Limnol Oceanogr Letters

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“…al., 2007, Hill et. al., 2005and Chen, 2010. Similarly other indices implicating municipal waste discharges on the stream systems are the high total coliform and faecal coliform concentrations observed in the water bodies which are below concentrations recorded in most of the systems in the past studies (Amadi et.…”

Section: Discussionmentioning

confidence: 93%

“…al., 2005. The study shows that the rapid growth of Port Harcourt and associated municipal wastes introduced into the five main steams have caused the deterioration of the water quality of the streams and therefore presents the need for a better waste management system (Chen, 2010).…”

Section: Discussionmentioning

confidence: 99%

Water Quality of Streams Receiving Municipal Waste Water in Port Harcourt, Niger Delta, Nigeria

Chindah¹,

Braide²,

Obunwo³

2011

Waste Water - Evaluation and Management

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“…CH 4 ) out from the sediment to the water column(Figueiredo-Barros et al, 2009). High NH + 4 concentrations delay the nitrification process (conversion of NH + 4 into NO − 3 ), a key step in the loss of this compound, which, in large amounts, is toxic for the organisms that comprise the aquatic community(Chen, Cao, Song, & Zhou, 2010). Our results suggest that Naididae might control the accumulation and flux of organic matter, as well as of NH + 4 , in the bromeliad aquatic system.…”

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confidence: 77%

Changes in rainfall level and litter stoichiometry affect aquatic community and ecosystem processes in bromeliad phytotelmata

et al. 2019

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Both N deposition and changes in precipitation amount are important components of global change and affect aquatic ecosystem functioning by altering the detrital quality and detrital processing rates by macroinvertebrates and microorganisms. Changes in precipitation pattern can also modify the physical structure of the ecosystem, determining habitat availability for aquatic organisms. Although these drivers can individually affect ecosystem structure and functioning, their interactive effects are poorly understood. To better understand the combined effects of detritus quality and precipitation regime on the structure and function of aquatic ecosystems we manipulated litter quality, by modifying N:P stoichiometry and rainfall amount on tropical natural aquatic microcosms (water‐holding epiphytic bromeliads). We performed an orthogonal manipulation of litter N:P ratio (natural N:P and high N:P) and rainfall levels (current level and predicted 40% increase for south‐eastern Brazil) Changes in litter quality affected the abundance of the aquatic organisms inhabiting bromeliads, including algae and bacteria. However, changes in litter quality combined with changes in precipitation levels affected only one group of macroinvertebrates, the Naididae worms (Oligochaeta) an important group of detritivores in the bromeliad systems. These combined drivers also affected the decomposition of organic matter by changing coloured organic matter concentrations, fine particulate matter biomass, and NH4+ concentrations in bromeliad tanks. The NH4+ concentration in bromeliad water was positively related with Naididae abundance, suggesting that these worms can act as ecosystem engineers by boosting N cycling. In both N:P treatments we observed a 50% decrease in N flux from litter to bromeliad leaves due to increases in nutrient leaching from the tanks caused by rainfall. The combined effects of litter quality and changes in precipitation regimes altered the decomposition process and nutrient cycling in tank bromeliads, probably through changes in the abundance of some keystone species (e.g. Naididae). Aquatic macroinvertebrate community structure remained similar after manipulating precipitation, despite changes in the abundance of some species. Although some microorganisms were washed out of the system, their abundance inside the bromeliads remained stable. We conclude that the abundance of individuals belonging to aquatic communities in bromeliad phytotelmata are generally stable and resistant to changes in rainfall levels, but are sensitive to changes in litter quality. This experiment showed that the interactive effects of increased precipitation and N concentrations differed from the effects of either factor alone. As responses to changes in these factors were complex rather than additive, caution is required in predicting the outcomes of changes in both factors in freshwater ecosystems.

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Adverse Effects of Ammonia on Nitrification Process: the Case of Chinese Shallow Freshwater Lakes

Cited by 24 publications

References 50 publications

Ice duration drives winter nitrate accumulation in north temperate lakes

Ice duration drives winter nitrate accumulation in north temperate lakes

Water Quality of Streams Receiving Municipal Waste Water in Port Harcourt, Niger Delta, Nigeria

Changes in rainfall level and litter stoichiometry affect aquatic community and ecosystem processes in bromeliad phytotelmata

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