Combined impact of ocean acidification and corrosive waters in a river-influenced coastal upwelling area off Central Chile

Elevated CO2 in the atmosphere promotes a cascade of physical and chemical changes affecting all levels of biological organization, and the evidence from local to global scales has shown that such anthropogenic climate change has triggered significant responses in the Earth's biota. The increased concentration of CO2 is likely to cause a corresponding increase in ocean acidification (OA). In addition, economically valuable shellfish species predominantly inhabit coastal regions both in natural stocks and/or in managed stocks and farming areas. Many coastal ecosystems may experience seawater pCO2 levels significantly higher than expected from equilibrium with the atmosphere, which in this case are strongly linked to biological processes and/or the impact of two important processes; river plumes and coastal upwelling events, which indeed interplay in a very dynamic way on continental shelves, resulting in both source or sink of CO2 to the atmosphere. Coastal ecosystems receive persistent acid inputs as a result of freshwater discharges from river basins into the coastal domain. In this context, since shellfish resources and shellfish aquaculture activities predominantly occur in nearshore areas, it is expected that shellfish species inhabiting river-influenced benthic ecosystems will be exposed persistently to acidic conditions that are suboptimal for its development. In a wider ecological context, little is also known about the potential impacts of acid waters on the performance of larvae and juveniles of almost all the marine species inhabiting this benthic ecosystem in Eastern Southern Pacific Ocean. We present here the main results of a research study aimed to investigate the environmental conditions to which economically valuable calcifiers shellfish species are exposed in a river-influenced continental shelf off Central Chile. By using isotopic measurements in the dissolved inorganic carbon (DIC) pool (d13C-DIC) we showed the effect of the remineralization of organic matter due to natural or anthropogenically stimulated respiration processes within river basin may impact the coastal ocean. Furthermore, the upwelling of corrosive subsurface waters might also undersaturate coastal waters with respect to aragonite. In addition, by using a mesocosm system to simulate different pH and CO2 levels we have evaluate under controlled conditions the effect of ocean acidification on the larval stage of an economically-important gastropod species (Concholepas concholepas). In this presentation, we show some preliminary results using multi-source data from different research projects dealing with the carbon cycle and OA processes along Chilean coast. Funded by Project RIVOM (Fondecyt 1095069), Project TOA-SPACE (Fondecyt 1090624), and Project Anillo ACT132 (CONICYT).