The responses of plankton communities in experimental ponds to atrazine, the most heavily used pesticide in the United States

Experimental ponds received single additions of the herbicide atrazine in concentrations of 20 and 500 @mg/L, and were compared to control ponds for 136 d. Atrazine is an inhibitor of photosynthesis, and both concentrations depressed phytoplankton growth in the ponds within a few days. This was foll...

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Veröffentlicht in:	Ecology (Durham) 1982-10, Vol.63 (5), p.1285-1293
Hauptverfasser:	deNoyelles, F, Kettle, W.D, Sinn, D.E
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Sprache:	eng
Schlagworte:	Biomass Communities Fluorescence Pesticides Photosynthesis Phytoplankton Plankton Ponds Radiocarbon Zooplankton
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container_title	Ecology (Durham)
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creator	deNoyelles, F Kettle, W.D Sinn, D.E
description	Experimental ponds received single additions of the herbicide atrazine in concentrations of 20 and 500 @mg/L, and were compared to control ponds for 136 d. Atrazine is an inhibitor of photosynthesis, and both concentrations depressed phytoplankton growth in the ponds within a few days. This was followed by successional changes leading to the establishment of species of phytoplankton more resistant to inhibition by atrazine. Laboratory studies verified this resistance and verified effects on other species at concentrations of atrazine as low as 1-5 @mg/L. When and to what extent resistant species appeared in the phytoplankton communities differed with treatment. At the atrazine concentration of 500 @mg/L, there was a delayed appearance but eventually a greater biomass and persistent of these species. The grazing zooplankton influenced these differences and were in turn affected by them. Natural interactions such as competition and predation among the species of the communities greatly affected their responses to the toxic chemical. The importance of atrazine as an environmental pollutant is suggested by these responses to concentrations of 1-5 @mg/L, which are common downstream in many agricultural watersheds, 20@mg/L, which is the high level found in these waters, and 500 @mg/L, which is the high level found in waters directly adjacent to treated fields.
doi_str_mv	10.2307/1938856
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source	Jstor Complete Legacy; Periodicals Index Online
subjects	Biomass Communities Fluorescence Pesticides Photosynthesis Phytoplankton Plankton Ponds Radiocarbon Zooplankton
title	The responses of plankton communities in experimental ponds to atrazine, the most heavily used pesticide in the United States
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