Seawater carbonate chemistry and growth response of calcifying marine epibionts

In coastal marine environments, physical and biological forces can cause dynamic pH fluctuations from microscale (diffusive boundary layer [DBL]) up to ecosystem‐scale (benthic boundary layer [BBL]). In the face of ocean acidification (OA), such natural pH variations may modulate an organism's...

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Bibliographic Details
Main Authors: Johnson, Mildred Jessica, Hennigs, Laura Margarethe, Sawall, Yvonne, Pansch, Christian, Wall, Marlene
Format: Dataset
Language:English
Published: PANGAEA 2021
Subjects:
Alkalinity
total
standard deviation
Animalia
Aragonite saturation state
Arthropoda
Balanus improvisus
Baltic Sea
Benthic animals
Benthos
Bicarbonate ion
Bryozoa
Calcite saturation state
Calculated using seacarb
Calculated using seacarb after Nisumaa et al. (2010)
Carbon
inorganic
dissolved
Carbonate ion
Carbonate system computation flag
Carbon dioxide
Coast and continental shelf
Containers and aquaria (20-1000 L or < 1 m**2)
Electra pilosa
Experiment duration
Fugacity of carbon dioxide (water) at sea surface temperature (wet air)
Growth
Growth/Morphology
Growth efficency
Growth rate
Laboratory experiment
OA-ICC
Ocean Acidification International Coordination Centre
Other
Partial pressure of carbon dioxide
Partial pressure of carbon dioxide (water) at sea surface temperature (wet air)
pH
Position
Registration number of species
Ocean acidification
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.929951
https://doi.org/10.1594/PANGAEA.929951
Description
Summary:In coastal marine environments, physical and biological forces can cause dynamic pH fluctuations from microscale (diffusive boundary layer [DBL]) up to ecosystem‐scale (benthic boundary layer [BBL]). In the face of ocean acidification (OA), such natural pH variations may modulate an organism's response to OA by providing temporal refugia. We investigated the effect of pH fluctuations, generated by the brown alga Fucus serratus' biological activity, on the calcifying epibionts Balanus improvisus and Electra pilosa under OA. For this, both epibionts were grown on inactive and biologically active surfaces and exposed to (1) constant pH scenarios under ambient (pH 8.1) or OA conditions (pH 7.7), or (2) oscillating pH scenarios mimicking BBL conditions at ambient (pH 7.7–8.6) or OA scenarios (pH 7.4–8.2). Furthermore, all treatment combinations were tested at 10°C and 15°C. Against our expectations, OA treatments did not affect epibiont growth under constant or fluctuating (BBL) pH conditions, indicating rather high robustness against predicted OA scenarios. Furthermore, epibiont growth was hampered and not fostered on active surfaces (fluctuating DBL conditions), indicating that fluctuating pH conditions of the DBL with elevated daytime pH do not necessarily provide temporal refugia from OA. In contrast, results indicate that factors other than pH may play larger roles for epibiont growth on macrophytes (e.g., surface characteristics, macrophyte antifouling defense, or dynamics of oxygen and nutrient concentrations). Warming enhanced epibiont growth rates significantly, independently of OA, indicating no synergistic effects of pH treatments and temperature within their natural temperature range.

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