Reply on RC1

Abstract

<strong class="journal-contentHeaderColor">Abstract.</strong> The key processes driving the air–sea <span class="inline-formula">CO₂</span> fluxes in the western tropical Atlantic (WTA) in winter are poorly known. WTA is a highly dynamic oceanic region, expected to have a dominant role in the variability in <span class="inline-formula">CO₂</span> air–sea fluxes. In early 2020 (February), this region was the site of a large in situ survey and studied in wider context through satellite measurements. The North Brazil Current (NBC) flows northward along the coast of South America, retroflects close to 8<span class="inline-formula">^∘</span> N and pinches off the world's largest eddies, the NBC rings. The rings are formed to the north of the Amazon River mouth when freshwater discharge is still significant in winter (a time period of relatively low run-off). We show that in February 2020, the region (5–16<span class="inline-formula">^∘</span> N, 50–59<span class="inline-formula">^∘</span> W) is a <span class="inline-formula">CO₂</span> sink from the atmosphere to the ocean (<span class="inline-formula">−1.7</span> <span class="inline-formula">Tg C</span> per month), a factor of 10 greater than previously estimated. The spatial distribution of <span class="inline-formula">CO₂</span> fugacity is strongly influenced by eddies south of 12<span class="inline-formula">^∘</span> N. During the campaign, a nutrient-rich freshwater plume from the Amazon River is entrained by a ring from the shelf up to 12<span class="inline-formula">^∘</span> N leading to high phytoplankton concentration and significant carbon drawdown (<span class="inline-formula">∼20</span> % of the total sink). In trapping equatorial waters, NBC rings are a small source of <span class="inline-formula">CO₂</span>. The less variable North Atlantic subtropical water extends from 12<span class="inline-formula">^∘</span> N northward and represents <span class="inline-formula">∼60</span> % of the total sink due to the lower temperature associated with winter cooling and strong winds. Our results, in identifying the key processes influencing the air–sea <span class="inline-formula">CO₂</span> flux in the WTA, highlight the role of eddy interactions with the Amazon River plume. It sheds light on how a lack of data impeded a correct assessment of the flux in the past, as well as on the necessity of taking into account features at meso- and small scales.