Mechanisms controlling seasonal mixed layer temperature and salinity in the Southwestern Tropical Indian Ocean

► ECCO used to study seasonal MLT & MLS budgets over Indian Ocean thermocline ridge. ► For MLT: Surface heat flux & ocean processes, esp. vertical mixing, are important. ► Weak/negative seasonal SST-SSH correlation explained. ► Seasonal MLS dominated by v-advection; subsurface effects small...

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Bibliographic Details
Published in:Dynamics of atmospheres and oceans 2011-04, Vol.51 (3), p.77-93
Main Authors: Halkides, Daria, Lee, Tong
Format: Article
Language:English
Subjects:
Earth, ocean, space
Exact sciences and technology
External geophysics
Indian Ocean
Marine
Mixed layer budgets
Thermocline ridge
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Summary:► ECCO used to study seasonal MLT & MLS budgets over Indian Ocean thermocline ridge. ► For MLT: Surface heat flux & ocean processes, esp. vertical mixing, are important. ► Weak/negative seasonal SST-SSH correlation explained. ► Seasonal MLS dominated by v-advection; subsurface effects small (discussed). ► Work fills knowledge gaps regarding ML processes in this climatically important area. We use a heat- and salt-conserving ocean state estimation product to study the seasonal cycles of the mixed layer (ML) temperature (MLT) and salinity (MLS) balances over the southwestern tropical Indian Ocean (SWTIO) thermocline ridge (STR; 50°–75°E, 12°–5°S). For seasonal MLT, surface heat flux and ocean processes are both important. They tend to re-enforce each other during peak cooling (May–June) and warming (November) periods, but not during transition periods. The dominant ocean process is wind-driven vertical mixing. It is modulated by the variable strength of the monsoon winds (which affect the vertical diffusivity), and to a lesser extent by variability of thermocline depth (which influences the vertical stratification across the ML base). For example, thermocline shoaling in April–July alters the vertical stratification near the ML base; thus, when the monsoon winds heighten (June–September) and the vertical diffusivity increases (deepening the ML base), relatively cool subsurface water is near the ML base and easily incorporated into the ML by vertical mixing. However, vertical advection as a direct response to thermocline shoaling has little affect on MLT. This explains why MLT and thermocline depth are not positively correlated here on the seasonal timescale (as they are on the interannual timescale). Meridional advection associated with Ekman transport driven by the monsoon winds plays a secondary role. Seasonal MLS, however, is dominated by meridional advection. Vertical process effects on MLS are small, due to a weak salinity gradient near the ML base throughout the year.
ISSN:0377-0265
1872-6879
DOI:10.1016/j.dynatmoce.2011.03.002