Abstract:
By increasing Earth-atmosphere system albedo, Stratospheric Aerosol Geoengineering (SAG) using sulfur dioxide is an
artificial potential means, with the goal to mitigate the global warming effects. In this study, we used the simulations from
Geoengineering Large Ensemble project realized under the climate change scenario of Representative Concentration Pathway
8.5 (RCP8.5), to investigate the potential impact of SAG on the Sea Surface Temperature (SST) in Equatorial Atlantic Cold
Tongue (EACT) and the physical processes driving these changes. Results reveal that in the EACT region, under RCP8.5,
SST warms significantly (compared to present‐day climate) with a maximum of 1.7 °C in July, and this increase in SST is
mainly due to the local processes related to the weakening of vertical mixing at the base of the mixed layer. This reduction of
the vertical mixing is associated to the diminution of the vertical shear from July to April and to the increase of ocean stratification
from May to June. However, under SAG, SST decreases significantly throughout the year (compared to present‐day
climate) with a maximum cooling of − 0.4 °C in the cold tongue period (May–June). This SST cooling is mainly associated
with the non-local processes related to intensification of the westerly equatorial Atlantic wind stress. Finally, results show that
the use of SAG to offset all global warming under RCP8.5 results in a slight over compensation of SST in the EACT region.
