Adrift Upon a Salinity-Stratified Sea: A View of Upper-Ocean Processes in the Bay of Bengal During the Southwest Monsoon

Andrew Lucas,Arnaud Le Boyer,Debasis Sengupta,Amala Mahadevan,Jennifer Mackinnon,M Ravichandran,Melissa Omand,Mara Freilich,Jonathan Nash,Robert Pinkel,Amit Tandon

doi:10.5670/oceanog.2016.46

Abstract

The structure and variability of upper-ocean properties in the Bay of Bengal (BoB) modulate air-sea interactions, which profoundly influence the pattern and intensity of monsoonal precipitation across the Indian subcontinent. In turn, the bay receives a massive amount of freshwater through river input at its boundaries and from heavy local rainfall, leading to a salinity-stratified surface ocean and shallow mixed layers. Small-scale oceanographic processes that drive variability in near-surface BoB waters complicate the tight coupling between ocean and atmosphere implicit in this seasonal feedback. Unraveling these ocean dynamics and their impact on air-sea interactions is critical to improving the forecasting of intraseasonal variability in the southwest monsoon. To that end, we deployed a wave-powered, rapidly profiling system capable of measuring the structure and variability of the upper 100 m of the BoB. The evolution of upper-ocean structure along the trajectory of the instrument's roughly two-week drift, along with direct estimates of vertical fluxes of salt and heat, permit assessment of the contributions of various phenomena to temporal and spatial variability in the surface mixed layer depth. Further, these observations suggest that the particular ``barrier-layer'' stratification found in the BoB may decrease the influence of the wind on mixing processes in the interior, thus isolating the upper ocean from the interior below, and tightening its coupling to the atmosphere above.

Highlights

The motivation for the US Air-Sea Interactions Regional Initiative (ASIRI) and India’s Ocean Mixing and Monsoon (OMM) program lies in the lack of skill of numerical models to reproduce sea surface temperatures (SST) in the Bay of Bengal (BoB; Goswami et al, 2016, in this issue)
“We expect that the quantitative assessment of these mechanisms will provide better prediction of sea surface temperature and the associated air-sea coupling over the Bay of Bengal, yielding increased fidelity in monsoon weather
The interior heat fluxes reported here are small compared to atmospheric fluxes, suggesting that (1) the mixed layer responds directly to atmospheric forcing on a daily cycle with little internal redistribution of heat by turbulence, (2) lateral advective processes are important in redistributing heat, or (3) interior mixing occurs in isolated, intense events, such as beneath the front that was sampled here, which is spatially localized but persistent in time, or other nonlinear features such as the bore reported in Sarkar et al (2016, in this issue)

Summary

Introduction

The motivation for the US Air-Sea Interactions Regional Initiative (ASIRI) and India’s Ocean Mixing and Monsoon (OMM) program lies in the lack of skill of numerical models to reproduce sea surface temperatures (SST) in the Bay of Bengal (BoB; Goswami et al, 2016, in this issue). The evolution of upper-ocean structure along the trajectory of the instrument’s roughly two-week drift, along with direct estimates of vertical fluxes of salt and heat, permit assessment of the contributions of various phenomena to temporal and spatial variability in the surface mixed layer depth.

Results

Conclusion