Formation and Maintenance of the Southern Bay of Bengal Cold Pool

Das, Umasankar

January 2015

Around Sri Lanka and to the south of India sea surface temperatures (SST) are cooler compared to the surrounding region during summer monsoon. This region where SSTs are relatively cooler is known as the cold pool. Owing to its possible impact on monsoon variability, some studies have been carried out to understand the evolution of cold pool SST during this period. These studies suggest, coastal upwelling along southern coast of Sri Lanka and eastward advection of cooler water contributes to the decrease in SST during summer monsoon. However, the processes leading to the formation of cold pool, still, remain unknown. In this study, we have investigated the mechanism responsible for the formation and maintenance of southern Bay of Bengal (BOB) cold pool using high resolution satellite data, model simulations and in-situ observations for the year 2009. Our study reveals formation of cold pool is dominated by atmospheric processes, whereas oceanic processes dominate its maintenance. Cooling of SSTs during premonsoon and onset phase acts as a prerequisites for the formation of cold pool, which are linked to the reduction in Net Heat flux (NHFX) during theses periods. The changes in NHFX during premonsoon and onset phase are dominated by reduction in Short-wave (SW) radiation associated with strong convective activity over cold pool. Convective activity over the cold pool are associated with the northward movement of Maximum Cloud Zone (MCZ) that forms over Equatorial Indian Ocean (EIO) during these periods. SST within the cold pool after the steady increase during February-April months, cools first during premonsoon rain event and then during monsoon onset. Analysis of high resolution satellite data for the period 2003-2009 suggest that, these sequence of events occurs with minor amount of inter-annual variability. Lead-lag correlation also made it clear that SST response in 5 days to the corresponding variation in atmospheric processes. SST within the cold pool shows several intraseasonal cooling events during the summer mon-soon. Considering that rainfall above the cold pool is very low during the summer monsoon, these cooling events occurring within the summer should be necessary for maintaining the cold pool. The seasonal evolution of SST shows that it continues to decrease till the end of the summer monsoon. In-situ data collected during CTCZ field program in 2009, at two time series locations (TSL) and model simulations were used to determine the processes responsible for such cooling events. To estimate the contribution from advection to the observed SST tendency at fixed location, a measurement stratergy called ‘opertaion advection’ was used in this study. This stratergy involves measurement of oceanographic parameters along four edges from TSL directod along North, South, East and West for estimation of horizontal temperature gradients. Our results from SST cooling events captured by CTD at two fixed locations suggests that horizontal advection and entrainment dominate the SST evolution. Model temperature equation evaluated near the TSLs are convinient with the observations and suggest that atmospheric forcing is not responsible for intraseasonal cooling events.

Ocean Temperature

Sea Surface Temperature

Bay of Bengal Cold Pool

Cold Pool Sea Surface Temperatures

Cold Pool

Intraseasonal Cooling

Indian Ocean Warm Pool

Sea Surface Temperature Cooling

Air-Sea Fluxes

Air-Sea Heat Flux

Atmospheric and Oceanic Sciences

Mécanismes de la variabilité thermique interannuelle à décennale de l’océan supérieur dans la région du bord ouest du Pacifique Nord / Mechanisms of the interannual to decadal thermal variability of the upper ocean in the western boundary region of North Pacific

Pak, Gyun-Do

22 November 2016

La variabilité du contenu de chaleur hivernal de l'océan supérieur et ses mécanismes de causalité ont été étudiés en utilisant des observations et des produits de réanalyse dans le Pacifique Nord-Ouest. La relation entre la mousson d'hiver dans l'Asie de l'Est (EAWM) et l'Oscillation du Pacifique Nord (NPO) et leurs impacts sur la température de surface de la mer (SST) sont non stationnaires, avec un changement soudain en 1987/1988. L'EAWM et la NPO, qui étaient bien corrélées en 1973-1987, ne sont pratiquement plus corrélées en 1988-2002. Cette relation non stationnaire est liée au fort affaiblissement décennal de la haute pression Sibérienne après le changement de régime en 1988, ainsi qu'au changement concomitant du dipôle de la NPO positive. L'influence de l'EAWM et de la NPO sur la SST hivernale dans la région d'étude a significativement diminué après 1990. Le bilan de chaleur dans les 400 premiers mètres a été analysé à l'aide des sorties d'un modèle de la circulation océanique générale à haute résolution. Le taux de stockage de chaleur hivernal des échelles interannuelles à décennales est principalement déterminé par l'advection océanique plutôt que par le flux net de chaleur air-mer. Le rôle de l'advection de chaleur devient particulièrement important après le changement de régime en 1990, en association avec la réduction de la variabilité du flux de chaleur en surface causée par une faible variabilité de la SST. Le flux net de chaleur air-mer freine les anomalies thermiques créées par la dynamique océanique associée avec le déplacement méridien du front de l'Extension de l'Oyashio, qui est fortement corrélé avec les modes de téléconnexion de WP et PNA. / Winter upper-ocean heat content variability and its causal mechanisms are investigated using observational and reanalysis products in the western North Pacific. The relationship between the East Asian winter monsoon (EAWM) and the North Pacific Oscillation (NPO) and their impact on the sea surface temperature (SST) are nonstationary, with a sudden change at 1987/1988. During the 1973-87, the EAWM and NPO were significantly correlated to each other, but their correlation practically vanishes during the 1988-2002. This nonstationary relationship is related to the pronounced decadal weakening of the Siberian high after the 1988 regime shift as well as the concomitant positive NPO-like dipole change. The influence of EAWM and NPO to the winter SST in the study region is significantly decreased after the sudden change near-1990. The upper 400 m heat budget in the western North Pacific is analyzed using outputs from a high resolution ocean general circulation model. Winter heat storage rate on interannual to decadal time scales is mainly determined by oceanic heat advection rather than by net air-sea heat flux. The role of heat advection becomes particularly prominent after the 1990 regime shift in association with the reduced variability of surface heat flux caused by weakened SST variability. The net heat flux acts to dampen temperature anomalies caused by the ocean dynamics principally associated with the meridional shift of the Oyashio Extension front, which is significantly correlated with the West Pacific (WP) and Pacific-North America (PNA) teleconnection patterns.

Bilan de chaleur

Variabilité décennale

Advection océanique

Flux de chaleur air-mer

Kuroshio-Oyashio Extension

Changement de régime

Heat budget

Long-term variability

Ocean advection

Air-sea heat flux

Kuroshio-Oyashio Extension

Regime shift

551.46

Réponse des masses d'eau intermédiaires et modales de l'océan Austral au mode annulaire austral : les processus en jeu et rôle de la glace de mer / Antarctic Intermediate and Subantarctic Mode waters response to the Southern Annular Mode : processes involved and the sea-ice role

Mainsant, Gildas

28 November 2014

Les tendances climatiques récentes montrent un réchauffement et un adoucissement des couches de surface dans la région du courant circumpolaire antarctique (ACC).Sur la même période, les vents d'ouest pilotant la circulation de l'océan Austral ont significativement augmentés. Cette augmentation est en partie liée à l'intensification du mode annulaire austral (SAM), principal mode de variabilité atmosphérique au sud de 20°S. Dans cette thèse, on s'intéresse à comprendre les effets de la tendance positive du SAM sur les propriétés des masses d'eau formées dans la région de l'ACC.A cette fin, on met en place une stratégie de simulations régionales couplées océan-glace de mer et forcées par une série de scénarios atmosphériques perturbés. Les scénarios atmosphériques sont construits à partir de réanalyses atmosphériques afin de décrire les différentes composantes (dynamiques et thermodynamiques) des changements liés au SAM.En réponse à l'intensification du SAM, les simulations montrent une forte salinisation de la couche de mélange océanique ainsi que des eaux modales (SAMW) et intermédiaires (AAIW).L'essentiel de ces changements peut être attribué aux composantes dynamiques du SAM. Dans les régions saisonnières englacées, les composantes thermodynamiques du SAM peuvent jouer un rôle important (en particulier en mer d'Amundsen et en mer de Weddell). Les simulations montrent également le rôle clef joué par la glacede mer dans la médiation des changements atmosphériques vers l'océan intérieur. Ces résultats de simulations suggèrent que le SAM ne serait pas le seul pilote des tendances climatiques récentes dans l'océan Austral. / Recent climate trends show a warming and freshening of the surface layers in the region of the Antarctic Circumpolar Current (ACC). Over the same period, the westerlies driving the circulation of the Southern Ocean have significantly increased. This increase is partly due to the intensification of the Southern Annular Mode (SAM), the main mode of atmospheric variability south of 20°S. In this thesis, we are interested in understanding the effects of the positive trend of the SAM onto the properties of water masses formed in the region of the ACC. To do so, we implement a strategy of regional coupled ocean-sea ice simulations forced by a series of atmospheric disturbance scenarios.These scenarios are constructed from atmospheric reanalyses in order to describe the various components (dynamic and thermodynamic) of the changes related to the SAM. In response to the increase of the SAM, the simulations show a significant salinification of the ocean mixed layer and of the mode water (SAMW) and intermediate water (AAIW).Most of these changes can be attributed to the dynamic components of the SAM. In Seasonal Ice Zone, the thermodynamic components of the SAM can play an important part (especially in Amundsen Sea and Weddell Sea). The simulations also show the key role played by sea ice in mediating atmospheric changes toward the interior ocean.These simulation results suggest that SAM is not the only driver of recent climate trends in the Southern Ocean.

Océan Austral

Flux air-mer de chaleur et d'eau douce

Mode Annulaire Austral

Masses d'eau océaniques

Southern Ocean

Air-sea heat flux

Air-sea freshwater flux

Southern Annular Mode

Oceanic water masses

550