A Case Study of System and Planktonic Responses in a Subtropical Warm Plume Receiving Thermal Effluents from a Power Plant
To explore planktonic and ecosystem responses to thermal effluents of a power plant, three transect surveys were conducted in Nov-01', May-02' and Jun-02' at the bay adjacent to the outlet of Taiwan Nuclear Power Plant II. At the given station, seasonal trends were evident with most m...
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| creator | 夏復國(Fuh-Kwo Shiah) 杜悅元(Yueh-Yuan Tu) 蔡顯修(Hsien-Shiow Tsai) 高樹基(Shuh-Ji Kao) 詹森(Sen Jan) |
| description | To explore planktonic and ecosystem responses to thermal effluents of a power plant, three transect surveys were conducted in Nov-01', May-02' and Jun-02' at the bay adjacent to the outlet of Taiwan Nuclear Power Plant II. At the given station, seasonal trends were evident with most maximal measurements observed in Jun-02'. Physical mixing between background seawater and thermal effluents played an important role in determining planktonic biomass since chlorophyll (Chl, < 0.15 - 1.27 mgChl m-3 ) and bacterial biomass (BB, 11 - 48 mgC m-3 ) increased almost linearly seaward. Temperature (20 - 45°C) manipulation experiments suggested that phytoplankton were more vulnerable than heterotrophs to thermal stress. Differential temperature responses of auto- and heterotrophs result in primary production (PP, < 1 - 100 mgC m-3 d-1 ) increasing seaward, while community respiration (CR, 15 - 68 mgC m-3 d-1 ) and bacterial growth rate (BGR, 0.03 - 0.9 d-1 ) showed opposite trends. The plume system was heterotrophic (PP/CR ratio < 1) in areas with bottom depths ca. < 10 m, and then switched to autotrophic status (PP/CR ratio > 1 - 3.7) in deeper regions. High observed dissolved organic carbon (DOC) anomaly (23 – 34 gC m-3 ) implied that heterotrophic metabolism was seldom limited by bottom- up control processes. Short-term manipulation experiments showing that BGR and CR increased with rising temperature up to ca. 37°C, which was ~12°C higher than frequently reported values from most coastal and estuarine ecosystems. We ascribed this to the effects of temperature-substrate interaction. The results of organic carbon (zooplankton extract) ad dition experiments suggested a certain fraction of the in situ DOC was as labile as animal tissue since the increasing trends of BGR in the enriched and control treatments behaved similarly. From a carbon cycling perspective, the positive temperature responses of heterotrophic activities imply that in coastal systems with a high loading of anthropogenic DOC, the biogenic emission rate of CO2 might increase exponentially as global temperatures rise. |
| doi_str_mv | 10.3319/TAO.2005.16.2.513(O) |
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At the given station, seasonal trends were evident with most maximal measurements observed in Jun-02'. Physical mixing between background seawater and thermal effluents played an important role in determining planktonic biomass since chlorophyll (Chl, < 0.15 - 1.27 mgChl m-3 ) and bacterial biomass (BB, 11 - 48 mgC m-3 ) increased almost linearly seaward. Temperature (20 - 45°C) manipulation experiments suggested that phytoplankton were more vulnerable than heterotrophs to thermal stress. Differential temperature responses of auto- and heterotrophs result in primary production (PP, < 1 - 100 mgC m-3 d-1 ) increasing seaward, while community respiration (CR, 15 - 68 mgC m-3 d-1 ) and bacterial growth rate (BGR, 0.03 - 0.9 d-1 ) showed opposite trends. The plume system was heterotrophic (PP/CR ratio < 1) in areas with bottom depths ca. < 10 m, and then switched to autotrophic status (PP/CR ratio > 1 - 3.7) in deeper regions. High observed dissolved organic carbon (DOC) anomaly (23 – 34 gC m-3 ) implied that heterotrophic metabolism was seldom limited by bottom- up control processes. Short-term manipulation experiments showing that BGR and CR increased with rising temperature up to ca. 37°C, which was ~12°C higher than frequently reported values from most coastal and estuarine ecosystems. We ascribed this to the effects of temperature-substrate interaction. The results of organic carbon (zooplankton extract) ad dition experiments suggested a certain fraction of the in situ DOC was as labile as animal tissue since the increasing trends of BGR in the enriched and control treatments behaved similarly. From a carbon cycling perspective, the positive temperature responses of heterotrophic activities imply that in coastal systems with a high loading of anthropogenic DOC, the biogenic emission rate of CO2 might increase exponentially as global temperatures rise.</description><identifier>ISSN: 1017-0839</identifier><identifier>EISSN: 2311-7680</identifier><identifier>DOI: 10.3319/TAO.2005.16.2.513(O)</identifier><language>eng</language><publisher>Taiwan: 中華民國地球科學學會</publisher><subject>Animal tissues ; Anthropogenic factors ; Biogenic emissions ; Biomass ; Brackishwater environment ; Carbon ; Carbon cycle ; Carbon dioxide ; Case studies ; Chlorophyll ; Chlorophylls ; Dissolved organic carbon ; Effluents ; Estuaries ; Estuarine ecosystems ; Estuarine environments ; Experiments ; Global temperatures ; Growth rate ; Heterotrophic organisms ; Heterotrophs ; Metabolism ; Nuclear energy ; Nuclear power plants ; Organic carbon ; Phytoplankton ; Primary production ; Seawater ; Substrates ; Surveys ; Temperature effects ; Thermal effluents ; Thermal pollution ; Thermal stress ; Trends ; Zooplankton</subject><ispartof>TAO : Terrestrial, atmospheric, and oceanic sciences, 2005-06, Vol.16 (2), p.513-528</ispartof><rights>2005. 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At the given station, seasonal trends were evident with most maximal measurements observed in Jun-02'. Physical mixing between background seawater and thermal effluents played an important role in determining planktonic biomass since chlorophyll (Chl, < 0.15 - 1.27 mgChl m-3 ) and bacterial biomass (BB, 11 - 48 mgC m-3 ) increased almost linearly seaward. Temperature (20 - 45°C) manipulation experiments suggested that phytoplankton were more vulnerable than heterotrophs to thermal stress. Differential temperature responses of auto- and heterotrophs result in primary production (PP, < 1 - 100 mgC m-3 d-1 ) increasing seaward, while community respiration (CR, 15 - 68 mgC m-3 d-1 ) and bacterial growth rate (BGR, 0.03 - 0.9 d-1 ) showed opposite trends. The plume system was heterotrophic (PP/CR ratio < 1) in areas with bottom depths ca. < 10 m, and then switched to autotrophic status (PP/CR ratio > 1 - 3.7) in deeper regions. High observed dissolved organic carbon (DOC) anomaly (23 – 34 gC m-3 ) implied that heterotrophic metabolism was seldom limited by bottom- up control processes. Short-term manipulation experiments showing that BGR and CR increased with rising temperature up to ca. 37°C, which was ~12°C higher than frequently reported values from most coastal and estuarine ecosystems. We ascribed this to the effects of temperature-substrate interaction. The results of organic carbon (zooplankton extract) ad dition experiments suggested a certain fraction of the in situ DOC was as labile as animal tissue since the increasing trends of BGR in the enriched and control treatments behaved similarly. From a carbon cycling perspective, the positive temperature responses of heterotrophic activities imply that in coastal systems with a high loading of anthropogenic DOC, the biogenic emission rate of CO2 might increase exponentially as global temperatures rise.</description><subject>Animal tissues</subject><subject>Anthropogenic factors</subject><subject>Biogenic emissions</subject><subject>Biomass</subject><subject>Brackishwater environment</subject><subject>Carbon</subject><subject>Carbon cycle</subject><subject>Carbon dioxide</subject><subject>Case studies</subject><subject>Chlorophyll</subject><subject>Chlorophylls</subject><subject>Dissolved organic carbon</subject><subject>Effluents</subject><subject>Estuaries</subject><subject>Estuarine ecosystems</subject><subject>Estuarine environments</subject><subject>Experiments</subject><subject>Global temperatures</subject><subject>Growth rate</subject><subject>Heterotrophic 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sciences</jtitle><date>2005-06-01</date><risdate>2005</risdate><volume>16</volume><issue>2</issue><spage>513</spage><epage>528</epage><pages>513-528</pages><issn>1017-0839</issn><eissn>2311-7680</eissn><abstract>To explore planktonic and ecosystem responses to thermal effluents of a power plant, three transect surveys were conducted in Nov-01', May-02' and Jun-02' at the bay adjacent to the outlet of Taiwan Nuclear Power Plant II. At the given station, seasonal trends were evident with most maximal measurements observed in Jun-02'. Physical mixing between background seawater and thermal effluents played an important role in determining planktonic biomass since chlorophyll (Chl, < 0.15 - 1.27 mgChl m-3 ) and bacterial biomass (BB, 11 - 48 mgC m-3 ) increased almost linearly seaward. Temperature (20 - 45°C) manipulation experiments suggested that phytoplankton were more vulnerable than heterotrophs to thermal stress. Differential temperature responses of auto- and heterotrophs result in primary production (PP, < 1 - 100 mgC m-3 d-1 ) increasing seaward, while community respiration (CR, 15 - 68 mgC m-3 d-1 ) and bacterial growth rate (BGR, 0.03 - 0.9 d-1 ) showed opposite trends. The plume system was heterotrophic (PP/CR ratio < 1) in areas with bottom depths ca. < 10 m, and then switched to autotrophic status (PP/CR ratio > 1 - 3.7) in deeper regions. High observed dissolved organic carbon (DOC) anomaly (23 – 34 gC m-3 ) implied that heterotrophic metabolism was seldom limited by bottom- up control processes. Short-term manipulation experiments showing that BGR and CR increased with rising temperature up to ca. 37°C, which was ~12°C higher than frequently reported values from most coastal and estuarine ecosystems. We ascribed this to the effects of temperature-substrate interaction. The results of organic carbon (zooplankton extract) ad dition experiments suggested a certain fraction of the in situ DOC was as labile as animal tissue since the increasing trends of BGR in the enriched and control treatments behaved similarly. From a carbon cycling perspective, the positive temperature responses of heterotrophic activities imply that in coastal systems with a high loading of anthropogenic DOC, the biogenic emission rate of CO2 might increase exponentially as global temperatures rise.</abstract><cop>Taiwan</cop><pub>中華民國地球科學學會</pub><doi>10.3319/TAO.2005.16.2.513(O)</doi><tpages>16</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | Animal tissues Anthropogenic factors Biogenic emissions Biomass Brackishwater environment Carbon Carbon cycle Carbon dioxide Case studies Chlorophyll Chlorophylls Dissolved organic carbon Effluents Estuaries Estuarine ecosystems Estuarine environments Experiments Global temperatures Growth rate Heterotrophic organisms Heterotrophs Metabolism Nuclear energy Nuclear power plants Organic carbon Phytoplankton Primary production Seawater Substrates Surveys Temperature effects Thermal effluents Thermal pollution Thermal stress Trends Zooplankton |
| title | A Case Study of System and Planktonic Responses in a Subtropical Warm Plume Receiving Thermal Effluents from a Power Plant |
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