Oxygen and carbon fluxes from shallow unvegetated sediments in the Clarence Estuary, NSW, Australia under warming and ocean acidification conditions

Dissolved organic/inorganic carbon and oxygen fluxes from whole sediment core incubations subject to temperature and ocean acidification manipulations. Estuaries make a disproportionately large contribution of dissolved organic carbon (DOC) to the global carbon cycle, but it is unknown how this will...

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Bibliographic Details
Main Authors: Simone, Michelle, Schulz, Kai, Oakes, Joanne, Eyre, Bradley D
Format: Dataset
Language:English
Published: PANGAEA 2020
Subjects:
AIRICA analyzer (Miranda)
Australia
Carbon
inorganic
dissolved
organic
Clarence_Estuary
DEPTH
sediment/rock
water
estuaries
EXP
Experiment
LDO-probe
Ocean acidification
Oxygen saturation
pH
pH probe
Replicates
Salinity
SALINO
Salinometer
sediment
Surface area
Temperature
Temperature sensor
Time in minutes
Time point
descriptive
TOC analyser (Aurora 1030W)
Treatment
Volume
warming
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.924460
https://doi.org/10.1594/PANGAEA.924460
Description
Summary:Dissolved organic/inorganic carbon and oxygen fluxes from whole sediment core incubations subject to temperature and ocean acidification manipulations. Estuaries make a disproportionately large contribution of dissolved organic carbon (DOC) to the global carbon cycle, but it is unknown how this will change under a future climate. As such, the response of DOC fluxes from microbially dominated unvegetated sediments to individual and combined future climate stressors of warming (from Δ-3 °C to Δ+5 °C on ambient mean temperatures) and ocean acidification (OA, ~2 times the current partial pressure of CO2, pCO2) was investigated ex situ. Warming alone increased sediment heterotrophy, resulting in a proportional increase in sediment DOC uptake, with sediments becoming net sinks of DOC (3.5 to 8.8 mmol-C m-2 d-1) at warmer temperatures (Δ+3 °C and Δ+5 °C, respectively). This temperature response changed under OA conditions, with sediments becoming more autotrophic and a greater sink of DOC (1 to 4 times greater than under current-pCO2). This response was attributed to the stimulation of heterotrophic bacteria with the autochthonous production of labile organic matter by microphytobenthos. Extrapolating these results to the global area of unvegetated subtidal estuarine sediments, the future climate of warming (Δ+3 °C) and OA may decrease the estuarine export of DOC by ~80 % (~150 Tg-C yr-1) and have a disproportionately large impact on the global DOC budget.

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