Emission of Carbon Dioxide and Methane from Duckweed Ponds for Stormwater Treatment

This study determined the greenhouse gas emission from two laboratory-scale duckweed ponds for stormwater treatment. The rate of carbon dioxide (CO2) emission from the two duckweed systems was 1472 ± 721 mg/m2·d and 626 ± 234 mg/m2·d, respectively. After the removal of duckweeds, CO2 emissions decre...

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Veröffentlicht in:	Water environment research 2015-09, Vol.87 (9), p.805-812
Hauptverfasser:	Dai, Jingjing, Zhang, Chiqian, Lin, Chung-Ho, Hu, Zhiqiang
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Sprache:	eng
Schlagworte:	Air Pollutants - analysis Aquatic plants Araceae - metabolism Carbon dioxide Carbon Dioxide - analysis duckweed pond Emissions greenhouse gas Methane Methane - analysis methanogens methanotrophs Missouri nutrient removal Ponds Rain Stormwater stormwater treatment Water Movements Water Purification Water treatment
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container_title	Water environment research
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creator	Dai, Jingjing Zhang, Chiqian Lin, Chung-Ho Hu, Zhiqiang
description	This study determined the greenhouse gas emission from two laboratory-scale duckweed ponds for stormwater treatment. The rate of carbon dioxide (CO2) emission from the two duckweed systems was 1472 ± 721 mg/m2·d and 626 ± 234 mg/m2·d, respectively. After the removal of duckweeds, CO2 emissions decreased to 492 ± 281 mg/m2·d and 395 ± 53 mg/m2·d, respectively. The higher CO2 emissions in the duckweed systems were attributed to duckweed biomass decay on the pond soil surface. A thin-film model was able to predict the increasing CO2 concentrations in the closed static chamber during 2 weeks of sampling. The initial methane fluxes from the duckweed systems were 299 ± 74 mg/m2·d and 180 ± 91 mg/m2·d, respectively. After the removal of duckweeds, the flux increased to 559 ± 215 mg/m2·d and 328 ± 114 mg/m2·d, respectively.
doi_str_mv	10.2175/106143015x14362865226310
format	Article
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The rate of carbon dioxide (CO2) emission from the two duckweed systems was 1472 ± 721 mg/m2·d and 626 ± 234 mg/m2·d, respectively. After the removal of duckweeds, CO2 emissions decreased to 492 ± 281 mg/m2·d and 395 ± 53 mg/m2·d, respectively. The higher CO2 emissions in the duckweed systems were attributed to duckweed biomass decay on the pond soil surface. A thin-film model was able to predict the increasing CO2 concentrations in the closed static chamber during 2 weeks of sampling. The initial methane fluxes from the duckweed systems were 299 ± 74 mg/m2·d and 180 ± 91 mg/m2·d, respectively. 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The rate of carbon dioxide (CO2) emission from the two duckweed systems was 1472 ± 721 mg/m2·d and 626 ± 234 mg/m2·d, respectively. After the removal of duckweeds, CO2 emissions decreased to 492 ± 281 mg/m2·d and 395 ± 53 mg/m2·d, respectively. The higher CO2 emissions in the duckweed systems were attributed to duckweed biomass decay on the pond soil surface. A thin-film model was able to predict the increasing CO2 concentrations in the closed static chamber during 2 weeks of sampling. The initial methane fluxes from the duckweed systems were 299 ± 74 mg/m2·d and 180 ± 91 mg/m2·d, respectively. After the removal of duckweeds, the flux increased to 559 ± 215 mg/m2·d and 328 ± 114 mg/m2·d, respectively.</abstract><cop>United States</cop><pub>THE WATER ENVIRONMENT FEDERATION</pub><pmid>26961475</pmid><doi>10.2175/106143015x14362865226310</doi><tpages>8</tpages></addata></record>
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subjects	Air Pollutants - analysis Aquatic plants Araceae - metabolism Carbon dioxide Carbon Dioxide - analysis duckweed pond Emissions greenhouse gas Methane Methane - analysis methanogens methanotrophs Missouri nutrient removal Ponds Rain Stormwater stormwater treatment Water Movements Water Purification Water treatment
title	Emission of Carbon Dioxide and Methane from Duckweed Ponds for Stormwater Treatment
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