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Seawater carbonate chemistry and foraminiferal calcification
The response of the marine carbon cycle to changes in atmospheric CO2 concentrations will be determined, in part, by the relative response of calcifying and non-calcifying... -
Seawater carbonate chemistry and cuttlefish buoyancy
Carbon dioxide concentration in the atmosphere is expected to continue rising by 2100, leading to a decrease in ocean pH in a process known as ocean acidification (OA). OA can... -
Seawater carbonate chemistry and microzooplankton abundance
Aquatic ecosystems face a multitude of environmental stressors, including warming and acidification. While warming is expected to have a pronounced effect on plankton... -
Seawater carbonate chemistry and Nucella behavior
Local adaptation can cause predator populations to vary in traits and their effects on prey, but few studies have tested whether divergent predator populations respond... -
Seawater carbonate chemistry and copepod reproduction
The combined upwelling-El Niño (EN) event regulation of the numerically dominant Acartia tonsa (Crustacea, Copepoda) reproduction was examined in a year-round upwelling system... -
Seawater carbonate chemistry and coral calcification
Experiments with coral fragments (i.e. nubbins) have shown that net calcification is depressed by elevated PCO2. Evaluating the implications of this finding requires scaling of... -
Seawater carbonate chemistry and coral calcification
Coral reefs are constructed by calcifiers that precipitate calcium carbonate to build their shells or skeletons through the process of calcification. Accurately assessing coral... -
Opal chemistry of costal Antarctic sediments
During the last 50 years, the Antarctic Peninsula has experienced rapid warming with associated retreat of 87% of marine and tidewater glacier fronts. Accelerated glacial... -
Seawater carbonate chemistry and mussel attachment
Predicting how combinations of stressors will affect failure risk is a key challenge for the field of ecomechanics and, more generally, ecophysiology. Environmental conditions... -
LTER Zöbelboden, Austria, Precipitation chemistry, 2021
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2021 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2020
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2020 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2022
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2022 -
LTER Zöbelboden, Austria, Throughfall chemistry, 2020
Throughfall chemistry of different forest plots of LTER Zöbelboden from the year 2020 -
LTER Zöbelboden, Austria, Throughfall chemistry, 2021
Throughfall chemistry of different forest plots of LTER Zöbelboden from the year 2021 -
LTER Zöbelboden, Austria, Throughfall chemistry, 2022
Throughfall chemistry of different forest plots of LTER Zöbelboden from the year 2022 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2016
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2016 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2018
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2018 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2017
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2017 -
LTER Zöbelboden, Austria, Precipitation chemistry, 2019
Precipitation chemistry of a karst watershed (Zöbelboden) from the year 2019 -
LTER Zöbelboden, Austria, Throughfall chemistry, 2019
Throughfall chemistry of different forest plots of LTER Zöbelboden from the year 2019
