Seawater carbonate chemistry and maximum quantum yield and relative electron transfer rate of microalgal communities in Antarctic pack ice

Increased anthropogenic CO2 emissions are causing changes to oceanic pH and CO2 concentrations that will impact many marine organisms, including microalgae. Phytoplankton taxa have shown mixed responses to these changes with some doing well while others have been adversely affected. Here, the photos...

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Bibliographic Details
Main Authors: Coad, Thomas, McMinn, Andrew, Nomura, Daiki, Martin, Andrew
Format: Dataset
Language:English
Published: PANGAEA 2016
Subjects:
Alkalinity
total
Antarctic
Aragonite saturation state
Bicarbonate ion
Bottles or small containers/Aquaria (<20 L)
Calcite saturation state
Calculated using seacarb after Nisumaa et al. (2010)
Carbon
inorganic
dissolved
Carbonate ion
Carbonate system computation flag
Carbon dioxide
Chlorophyll a
Comment
Entire community
Event label
EXP
Experiment
Fugacity of carbon dioxide (water) at sea surface temperature (wet air)
Incubation duration
Laboratory experiment
Light saturation
Maximal electron transport rate
relative
Maximum quantum yield of photosystem II
OA-ICC
Ocean Acidification International Coordination Centre
Open ocean
Partial pressure of carbon dioxide (water) at sea surface temperature (wet air)
Pelagos
pH
Photosynthetic quantum efficiency
Polar
Primary production/Photosynthesis
Salinity
SIPEX-2_station__4
SIPEX-2_station__7
SIPEX-2_station__8
Station label
Temperature
water
Treatment
Type
Austral
Antarc*
ice algae
Ocean acidification
Sea ice
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.933802
https://doi.org/10.1594/PANGAEA.933802
Description
Summary:Increased anthropogenic CO2 emissions are causing changes to oceanic pH and CO2 concentrations that will impact many marine organisms, including microalgae. Phytoplankton taxa have shown mixed responses to these changes with some doing well while others have been adversely affected. Here, the photosynthetic response of sea-ice algal communities from Antarctic pack ice (brine and infiltration microbial communities) to a range of CO2 concentrations (400 ppm to 11,000 ppm in brine algae experiments, 400 ppm to 20,000 ppm in the infiltration ice algae experiment) was investigated. Incubations were conducted as part of the Sea-Ice Physics and Ecosystem Experiment II (SIPEX-2) voyage, in the austral spring (September–November), 2012. In the brine incubations, maximum quantum yield (Fv/Fm) and relative electron transfer rate (rETRmax) were highest at ambient and 0.049% (experiment 1) and 0.19% (experiment 2) CO2 concentrations, although, Fv/Fm was consistently between 0.53±0.10–0.68±0.01 across all treatments in both experiments. Highest rETRmax was exhibited by brine cultures exposed to ambient CO2 concentrations (60.15). In a third experiment infiltration ice algal communities were allowed to melt into seawater modified to simulate the changed pH and CO2 concentrations of future springtime ice-edge conditions. Ambient and 0.1% CO2 treatments had the highest growth rates and Fv/Fm values but only the highest CO2 concentration produced a significantly lower rETRmax. These experiments, conducted on natural Antarctic sea-ice algal communities, indicate a strong level of tolerance to elevated CO2 concentrations and suggest that these communities might not be adversely affected by predicted changes in CO2 concentration over the next century.

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