Abstract
Surface ocean CO2 measurements are used to compute the oceanic air–sea CO2 flux. The CO2 flux component from rivers and estuaries is uncertain. Estuarine and coastal water carbon dioxide (CO2) observations are relatively few compared to observations in the open ocean. The contribution of these regions to the global air–sea CO2 flux remains uncertain due to systematic under-sampling. Existing high-quality CO2 instrumentation predominantly utilise showerhead and percolating style equilibrators optimised for open ocean observations. The intervals between measurements made with such instrumentation make it difficult to resolve the fine-scale spatial variability of surface water CO2 at timescales relevant to the high frequency variability in estuarine and coastal environments. Here we present a novel dataset with unprecedented frequency and spatial resolution transects made at the Western Channel Observatory in the south west of the UK from June to September 2016, using a fast response seawater CO2 system. Novel observations were made along the estuarine–coastal continuum at different stages of the tide and reveal distinct spatial patterns in the surface water CO2 fugacity (fCO2) at different stages of the tidal cycle. Changes in salinity and fCO2 were closely correlated at all stages of the tidal cycle and suggest that the mixing of oceanic and riverine end members determines the variations in fCO2. The observations demonstrate the complex dynamics determining spatial and temporal patterns of salinity and fCO2 in the region. Spatial variations in observed surface salinity were used to validate the output of a regional high resolution hydrodynamic model. The model enables a novel estimate of the air–sea CO2 flux in the estuarine–coastal zone. Air–sea CO2 flux variability in the estuarine–coastal boundary region is dominated by the state of the tide because of strong CO2 outgassing from the river plume. The observations and model output demonstrate that undersampling the complex tidal and mixing processes characteristic of estuarine and coastal environment bias quantification of air-sea CO2 fluxes in coastal waters. The results provide a mechanism to support critical national and regional policy implementation by reducing uncertainty in carbon budgets.
Highlights
The ocean has taken up about a quarter of anthropogenic carbon dioxide (CO2) emissions to date, absorbing approximately 2.5 Pg C yr-1 (Friedlingstein et al, 2019)
The zone where estuarine waters meet coastal waters is a physically dynamic system influenced by riverine outflow, winds, 55 waves, and tidal cycles, pressure of CO2 in seawater (pCO2) is likely to vary where estuarine water and continental shelf water interact, yet there has been relatively little attention given to air–water CO2 fluxes in this zone (Cai, 2011)
The underway seawater system on the ship has an intake at 3 m depth, supplying seawater for measurements of pCO2, sea surface temperature (SST) and surface salinity (SBE45; Seabird Scientific, USA). 105 The underway system is turned off when the ship is shore side of the Breakwater to reduce the risk of heavy biofouling and the intake of large quantities of sediment and coastal debris
Summary
The ocean has taken up about a quarter of anthropogenic carbon dioxide (CO2) emissions to date, absorbing approximately 2.5 Pg C yr-1 (Friedlingstein et al, 2019). The global estuarine air–water CO2 flux remains highly uncertain, with estimates ranging from 0.09 to 0.78 Pg C yr-1 (Cai, 2011;Laruelle et al, 2010;Chen and Borges, 2009;Chen et al, 45 2013;Resplandy et al, 2018). The zone where estuarine waters meet coastal waters is a physically dynamic system influenced by riverine outflow, winds, 55 waves, and tidal cycles, pCO2 is likely to vary where estuarine water and continental shelf water interact, yet there has been relatively little attention given to air–water CO2 fluxes in this zone (Cai, 2011). Eulerian studies in the 60 estuarine zone have identified large tidal signals in pCO2 with data collected from research vessels (Borges and Frankignoulle, 1999;Jeffrey et al, 2018a) and from moorings or fixed sites (Dai et al, 2009;Jeffrey et al, 2018a;Li et al, 2018;Bakker et al, 1996;Call et al, 2015;Ferrón et al, 2007;Santos et al, 2012). Transects underway CO2 measurements have not been regularly 65 repeated through the transitional zone where estuaries connect with continental shelf waters
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