Carbonate chemistry dynamics and biological processes along a river–sea gradient (Gulf of Trieste, northern Adriatic Sea)

Carbonate chemistry dynamics and biological processes along a river–sea gradient (Gulf of Trieste, northern Adriatic Sea)

In this paper we investigated, for two years and with a bi-monthly frequency, how physical, chemical, and biological processes affect the marine carbonate system in a coastal area characterized by high alkalinity riverine discharge (Gulf of Trieste, northern Adriatic Sea, Mediterranean Sea). By comb...

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Bibliographic Details
Published in:Journal of marine systems Vol. 155; pp. 35 - 49
Main Authors: Ingrosso, Gianmarco, Giani, Michele, Cibic, Tamara, Karuza, Ana, Kralj, Martina, Del Negro, Paola
Format: Journal Article
Language:English
Published: Elsevier B.V 01-03-2016
Subjects:
Air–sea CO2 exchange
Bacteria
Bacterial carbon production
Biological
Carbon
Carbon dioxide
Carbonate system
Carbonates
Dissolution
Dynamical systems
Dynamics
Freshwater
Marine
Ocean acidification
Primary production
Riverine input
MED, Adriatic Sea
MED
MED, Italy, Friuli-Venezia Giulia, Trieste
Air–sea CO2 exchange
Riverine input
Carbonate system
Ocean acidification
Bacterial carbon production
Primary production
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Summary:In this paper we investigated, for two years and with a bi-monthly frequency, how physical, chemical, and biological processes affect the marine carbonate system in a coastal area characterized by high alkalinity riverine discharge (Gulf of Trieste, northern Adriatic Sea, Mediterranean Sea). By combining synoptic measurements of the carbonate system with in situ determinations of the primary production (14C incorporation technique) and secondary prokaryotic carbon production (3H-leucine incorporation) along a river–sea gradient, we showed that the conservative mixing between river endmember and off-shore waters was the main driver of the dissolved inorganic carbon (DIC) distribution and seasonal variation. However, during spring and summer seasons also the influence of biological uptake and release of DIC was significant. In the surface water of June 2012, the spreading and persistence of nutrient-rich freshwater stimulated the primary production (3.21μgCL−1h−1) and net biological DIC decrease (−100μmolkg−1), reducing the dissolved CO2 concentration and increasing the pHT. Below the pycnocline of August 2012, instead, an elevated bacterial carbon production rate (0.92μgCL−1h−1) was related with net DIC increase (92μmolkg−1), low dissolved oxygen concentration, and strong pHT reduction, suggesting the predominance of bacterial heterotrophic respiration over primary production. The flux of carbon dioxide estimated at the air–sea interface exerted a low influence on the seasonal variation of the carbonate system. A complex temporal and spatial dynamic of the air–sea CO2 exchange was also detected, due to the combined effects of seawater temperature, river discharge, and water circulation. On annual scale the system was a sink of atmospheric CO2. However, in summer and during elevated riverine discharges, the area close to the river's mouth acted as a source of carbon dioxide. Also the wind speed was crucial in controlling the air–sea CO2 exchange, with strong Bora events (a typical ENE wind of the Gulf of Trieste) that drastically increased the absorption (−32.2mmolm−2day−1) or the release (5.34mmolm−2day−1) of carbon dioxide. •We investigated the carbonate system dynamics along a river–sea gradient.•The conservative mixing was the main driver of DIC seasonal variation.•The influence of biological activity was significant during spring and summer.•On annual scale the system was a sink of atmospheric CO2.•The area close to the river's mouth acted as a source of carbon dioxide.
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content type line 23
ISSN:0924-7963
1879-1573
DOI:10.1016/j.jmarsys.2015.10.013