Contrasting controls on phytoplankton dynamics in two large, pre-alpine lakes imply differential responses to climate change

The effects of climate change on lake ecosystems are often complex. We examined how phytoplankton in two neighbouring, pre-alpine, large oligotrophic lakes with similar catchments and land uses are likely to respond to climate change. We hypothesised that (i) while their climates and landscape filte...

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Veröffentlicht in:	Hydrobiologia 2016-05, Vol.771 (1), p.131-150
Hauptverfasser:	Bayer, Tina K, Schallenberg, Marc, Burns, Carolyn W
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Sprache:	eng
Schlagworte:	Analysis Aquatic ecosystems Bioassays Biomedical and Life Sciences Brackish climate Climate change Climate effects dynamic models Ecology Ecosystems Environmental aspects Filters Freshwater & Marine Ecology Global temperature changes Global warming Lakes Land use landscapes Life Sciences mixing Mountain lakes Nutrients Oligotrophic lakes phenology Phytoplankton Plankton Primary Research Paper Water temperature watersheds Zoology
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description	The effects of climate change on lake ecosystems are often complex. We examined how phytoplankton in two neighbouring, pre-alpine, large oligotrophic lakes with similar catchments and land uses are likely to respond to climate change. We hypothesised that (i) while their climates and landscape filters were relatively similar, differences in in-lake biological, physical and chemical filters would influence the phytoplankton responses to climate and (ii) direct effects of warming on phytoplankton dynamics and productivity would be relatively minor compared to indirect effects, especially those influencing the lakes’ mixing regimes. We combined (i) dynamic modelling of the physical forcing of the lakes under climate change, (ii) multi-year field sampling of relevant biological, physical and chemical variables and (iii) bioassay experiments, to test our hypotheses. Water temperatures have warmed over recent decades in one lake, but not in the other. The warming lake showed evidence of incomplete mixing and phytoplankton layering in winter 2009, while the other lake did not. Such changes influenced the phytoplankton phenology, and incomplete winter mixing is common in similar deep, temperate lakes. Inhibited winter mixing and related indirect effects of climate warming appear to be key early drivers of climate change effects on the phytoplankton of deep, temperate lakes.
doi_str_mv	10.1007/s10750-015-2625-2
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The warming lake showed evidence of incomplete mixing and phytoplankton layering in winter 2009, while the other lake did not. Such changes influenced the phytoplankton phenology, and incomplete winter mixing is common in similar deep, temperate lakes. 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We examined how phytoplankton in two neighbouring, pre-alpine, large oligotrophic lakes with similar catchments and land uses are likely to respond to climate change. We hypothesised that (i) while their climates and landscape filters were relatively similar, differences in in-lake biological, physical and chemical filters would influence the phytoplankton responses to climate and (ii) direct effects of warming on phytoplankton dynamics and productivity would be relatively minor compared to indirect effects, especially those influencing the lakes’ mixing regimes. We combined (i) dynamic modelling of the physical forcing of the lakes under climate change, (ii) multi-year field sampling of relevant biological, physical and chemical variables and (iii) bioassay experiments, to test our hypotheses. Water temperatures have warmed over recent decades in one lake, but not in the other. The warming lake showed evidence of incomplete mixing and phytoplankton layering in winter 2009, while the other lake did not. Such changes influenced the phytoplankton phenology, and incomplete winter mixing is common in similar deep, temperate lakes. Inhibited winter mixing and related indirect effects of climate warming appear to be key early drivers of climate change effects on the phytoplankton of deep, temperate lakes.</abstract><cop>Cham</cop><pub>Springer International Publishing</pub><doi>10.1007/s10750-015-2625-2</doi><tpages>20</tpages></addata></record>
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subjects	Analysis Aquatic ecosystems Bioassays Biomedical and Life Sciences Brackish climate Climate change Climate effects dynamic models Ecology Ecosystems Environmental aspects Filters Freshwater & Marine Ecology Global temperature changes Global warming Lakes Land use landscapes Life Sciences mixing Mountain lakes Nutrients Oligotrophic lakes phenology Phytoplankton Plankton Primary Research Paper Water temperature watersheds Zoology
title	Contrasting controls on phytoplankton dynamics in two large, pre-alpine lakes imply differential responses to climate change
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