e winter (3 4–14 4%), spring (8 2–23 6%), summer (3 1–9 6%) and

e. winter (3.4–14.4%), spring (8.2–23.6%), summer (3.1–9.6%) and autumn (8.3–19.3%). The maximum seasonal stability of the Mediterranean SST occurred in the eastern Alboran sub-basin all the year round except in summer. In summer, the maximum seasonal stability occurred in the southern Levantine sub-basin. The minimum stability of the Mediterranean SST occurred in the northern Aegean and Adriatic sub-basins in autumn, winter and spring; the minimum stability occurred in the Gulf

of Lion and its surrounding area in summer. The variability of the JQ1 research buy Black Sea SST (annual COV, 42.5%) is twice that of the Mediterranean SST, indicating more extreme dynamics in the Black Sea, disproportionate to its relatively small area. However, the AAM sub-basin SST is significantly less variable than is the Mediterranean SST. The AAM sub-basin has two water masses: the source of the surface water mass is Atlantic Ocean surface check details water and that of the lower water mass is the Mediterranean outflow through the Strait of Gibraltar, which sinks rapidly in the AAM sub-basin to a depth of 1000 m (Delgado et al. 2001). Consequently, the AAM sub-basin SST is significantly affected by Atlantic water, which is characterised by low SST variability due to the Atlantic Ocean’s large area. This may explain

the low variability of the AAM sub-basin SST. Based on monthly data, there is a significant negative correlation between SST and NAOI, most markedly over the eastern Black Sea and the eastern Levantine sub-basin in autumn (Figure 5 and Table 1). Similarly, based on monthly data, there is a significant negative correlation between SST and the atmospheric parameters SLP, P and TCC, especially over the Levantine and Aegean sub-basins and in spring (Table 1 and Figure 5). The maximum positive correlation between the effect of τax on SST occurs over the Adriatic sub-basin (R > 0.54, n = 372), while the maximum negative correlation occurs along the Algerian coast (R < − 0.5, n = 372),

as seen in Figure 5. However, the direct correlation between τay and SST reaches its maximum positive level (R > 0.5, n = 372) over the eastern LPC sub-basin Etomidate and its maximum negative level over the western Levantine sub-basin (R < − 0.5, n = 372). The effects of τax and τay on the study area SST display seasonal behaviour, peaking in winter and autumn respectively. The monthly correlation between SST and T2m is high (R > 0.75, n = 372) throughout the study area, most markedly (R > 0.98, n = 372) over the central Ionian, Algerian and central Tyrrhenian sub-basins, and also over the southern Black Sea. The effect of T2m on SST is significant over 100% of the study area in all seasons except winter. In winter, the correlation between T2m and SST is significant over only 89% of the study area. This is in good agreement with the previous findings of Skliris et al. (2012). Skliris et al. (2011) demonstrated that T2m is highly correlated with the Mediterranean SST (R = 0.86, level of significance = 99%).

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