Microbial dinitrogen and nitrous oxide production in a small eutrophic reservoir: An in situ approach to quantifying hypolimnetic process rates

Nitrogen (N) dynamics within the hypolimnion of a thermally stratified reservoir were examined to test an in situ approach to measuring dinitrogen (N2) and nitrous oxide (N2O) production rates wherein hypolimnion gas accumulation is used to estimate N2 and N2O production. This previously unpublished...

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Veröffentlicht in:	Limnology and oceanography 2011-07, Vol.56 (4), p.1189-1199
Hauptverfasser:	Deemer, Bridget R., Harrison, John A., Whitling, Elliott W.
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Sprache:	eng
Schlagworte:	Animal and plant ecology Animal, plant and microbial ecology Aquatic environment Biological and medical sciences Data processing Eutrophic environments Fundamental and applied biological sciences. Psychology General aspects hypolimnion Limnology Nitrate Nitrification Nitrogen Nitrous oxide Reservoirs Seasonal variations Sediment-water interface Sediments Stratification summer Synecology Transformation Water column
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description	Nitrogen (N) dynamics within the hypolimnion of a thermally stratified reservoir were examined to test an in situ approach to measuring dinitrogen (N2) and nitrous oxide (N2O) production rates wherein hypolimnion gas accumulation is used to estimate N2 and N2O production. This previously unpublished approach provides a spatially integrated, time‐varying record of N transformation rates that fall well within the range of rates reported for other reservoir systems using other methods. Hypolimnion N2 production averaged 183 μmol N2‐N m−2 h−1 with higher rates observed early in a spring stratification event (538 μmol N2‐N m−2 h−1) and lower rates observed later in the same stratification event (90 μmol N2‐N m−2 h−1). Sediment incubation experiments and hypolimnion nitrate (NO−3) data show that, over the course of the summer, progressive NO−3 depletion at the sediment‐water interface limited N2 production and associated N removal. As rates of N2 production dropped off, rates of N2O production increased (from 4.62 μmol N2O‐N m−2 d−1 to 51 μmol N2O‐N m−2 d−1, averaging 26 μmol N2O‐N m−2 d−1), resulting in significant increases in N2O‐N : N2‐N ratios as the summer progressed. Also, whereas N2 production appeared to occur predominantly at the sediment‐water interface, N2O production was detected throughout the water column, suggesting a role for nitrification as a source of N2O. The use of hypolimnion accumulation to quantify N transformation rates can thus offer new insights into spatial and seasonal N transformation patterns in stratified or otherwise capped aquatic systems.
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This previously unpublished approach provides a spatially integrated, time‐varying record of N transformation rates that fall well within the range of rates reported for other reservoir systems using other methods. Hypolimnion N2 production averaged 183 μmol N2‐N m−2 h−1 with higher rates observed early in a spring stratification event (538 μmol N2‐N m−2 h−1) and lower rates observed later in the same stratification event (90 μmol N2‐N m−2 h−1). Sediment incubation experiments and hypolimnion nitrate (NO−3) data show that, over the course of the summer, progressive NO−3 depletion at the sediment‐water interface limited N2 production and associated N removal. As rates of N2 production dropped off, rates of N2O production increased (from 4.62 μmol N2O‐N m−2 d−1 to 51 μmol N2O‐N m−2 d−1, averaging 26 μmol N2O‐N m−2 d−1), resulting in significant increases in N2O‐N : N2‐N ratios as the summer progressed. 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This previously unpublished approach provides a spatially integrated, time‐varying record of N transformation rates that fall well within the range of rates reported for other reservoir systems using other methods. Hypolimnion N2 production averaged 183 μmol N2‐N m−2 h−1 with higher rates observed early in a spring stratification event (538 μmol N2‐N m−2 h−1) and lower rates observed later in the same stratification event (90 μmol N2‐N m−2 h−1). Sediment incubation experiments and hypolimnion nitrate (NO−3) data show that, over the course of the summer, progressive NO−3 depletion at the sediment‐water interface limited N2 production and associated N removal. As rates of N2 production dropped off, rates of N2O production increased (from 4.62 μmol N2O‐N m−2 d−1 to 51 μmol N2O‐N m−2 d−1, averaging 26 μmol N2O‐N m−2 d−1), resulting in significant increases in N2O‐N : N2‐N ratios as the summer progressed. Also, whereas N2 production appeared to occur predominantly at the sediment‐water interface, N2O production was detected throughout the water column, suggesting a role for nitrification as a source of N2O. The use of hypolimnion accumulation to quantify N transformation rates can thus offer new insights into spatial and seasonal N transformation patterns in stratified or otherwise capped aquatic systems.</description><subject>Animal and plant ecology</subject><subject>Animal, plant and microbial ecology</subject><subject>Aquatic environment</subject><subject>Biological and medical sciences</subject><subject>Data processing</subject><subject>Eutrophic environments</subject><subject>Fundamental and applied biological sciences. 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Psychology</topic><topic>General aspects</topic><topic>hypolimnion</topic><topic>Limnology</topic><topic>Nitrate</topic><topic>Nitrification</topic><topic>Nitrogen</topic><topic>Nitrous oxide</topic><topic>Reservoirs</topic><topic>Seasonal variations</topic><topic>Sediment-water interface</topic><topic>Sediments</topic><topic>Stratification</topic><topic>summer</topic><topic>Synecology</topic><topic>Transformation</topic><topic>Water column</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Deemer, Bridget R.</creatorcontrib><creatorcontrib>Harrison, John A.</creatorcontrib><creatorcontrib>Whitling, Elliott W.</creatorcontrib><collection>Pascal-Francis</collection><collection>CrossRef</collection><collection>Biotechnology Research Abstracts</collection><collection>Industrial and Applied Microbiology Abstracts (Microbiology A)</collection><collection>Pollution Abstracts</collection><collection>Technology Research Database</collection><collection>Environmental Sciences and Pollution Management</collection><collection>Engineering Research Database</collection><collection>Biotechnology and BioEngineering Abstracts</collection><jtitle>Limnology and oceanography</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Deemer, Bridget R.</au><au>Harrison, John A.</au><au>Whitling, Elliott W.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Microbial dinitrogen and nitrous oxide production in a small eutrophic reservoir: An in situ approach to quantifying hypolimnetic process rates</atitle><jtitle>Limnology and oceanography</jtitle><date>2011-07</date><risdate>2011</risdate><volume>56</volume><issue>4</issue><spage>1189</spage><epage>1199</epage><pages>1189-1199</pages><issn>0024-3590</issn><eissn>1939-5590</eissn><coden>LIOCAH</coden><abstract>Nitrogen (N) dynamics within the hypolimnion of a thermally stratified reservoir were examined to test an in situ approach to measuring dinitrogen (N2) and nitrous oxide (N2O) production rates wherein hypolimnion gas accumulation is used to estimate N2 and N2O production. This previously unpublished approach provides a spatially integrated, time‐varying record of N transformation rates that fall well within the range of rates reported for other reservoir systems using other methods. Hypolimnion N2 production averaged 183 μmol N2‐N m−2 h−1 with higher rates observed early in a spring stratification event (538 μmol N2‐N m−2 h−1) and lower rates observed later in the same stratification event (90 μmol N2‐N m−2 h−1). Sediment incubation experiments and hypolimnion nitrate (NO−3) data show that, over the course of the summer, progressive NO−3 depletion at the sediment‐water interface limited N2 production and associated N removal. As rates of N2 production dropped off, rates of N2O production increased (from 4.62 μmol N2O‐N m−2 d−1 to 51 μmol N2O‐N m−2 d−1, averaging 26 μmol N2O‐N m−2 d−1), resulting in significant increases in N2O‐N : N2‐N ratios as the summer progressed. 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subjects	Animal and plant ecology Animal, plant and microbial ecology Aquatic environment Biological and medical sciences Data processing Eutrophic environments Fundamental and applied biological sciences. Psychology General aspects hypolimnion Limnology Nitrate Nitrification Nitrogen Nitrous oxide Reservoirs Seasonal variations Sediment-water interface Sediments Stratification summer Synecology Transformation Water column
title	Microbial dinitrogen and nitrous oxide production in a small eutrophic reservoir: An in situ approach to quantifying hypolimnetic process rates
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