Abstract
Using satellite remote sensing data and re-analysis products for the period of 1993–2015, the variation of a large anticyclonic eddy, the so-called Great Whirl (GW), located in the Northwest Indian Ocean off the coast of Somali, and its impacts on atmosphere were investigated. The GW is generated in early summer and decays in late fall every year. The center of the GW is located at 7.73°N, 53.20°E. The mean lifetime, sea level anomaly (SLA) difference, sea surface temperature anomaly (SSTA), radius, normalized vorticity, eddy kinetic energy (EKE), and deformation rate are 169 days, 0.07 m, 0.83°C, 116.86 km, −0.53, 0.08 m2∙s-2, and 0.58, respectively. All these variables exhibit interannual variations. Composite analyses show that the maximum values of sea surface temperature (SST), wind, and water vapor anomalies occur in the northwest of the GW center. The fitting coefficient between the SST and wind speed anomaly is 1.1, indicating that, corresponding to 1 °C increases of the SST, the wind speed increases by about 1.1m∙s-1, and the fitting coefficient between the SST and water vapor anomaly is 0.45, indicating that water vapor increases by about 0.45 mm in response to 1 °C increases in the SST. In the vertical direction, the maximum and minimum values of vertical velocity anomalies and vertical transport of transient zonal momentum occur over the GW at about 900 hPa, and wind speed anomalies occur at about 950 hPa. Both the positive transport anomalies of transient zonal momentum and the positive vertical velocity anomalies on the west side of the GW can accelerate the wind speed in the lower level.
Highlights
The Arabian Sea, located in the northwestern Indian Ocean, is dominated by the monsoon system, with large seasonal reversals of winds [1]
This study mainly focuses on the mean state and the interannual variations of the Great Whirl (GW), and discusses the corresponding atmospheric responses
Based on the eddy dataset, sea level anomaly (SLA), and sea surface temperature (SST) data, we analyzed the basic characteristics of the GW in July
Summary
The Arabian Sea, located in the northwestern Indian Ocean, is dominated by the monsoon system, with large seasonal reversals of winds [1]. Using satellite and in situ observational data, Vecchi et al [15] confirmed that the western Arabian Sea exhibits strong air–sea coupling during the southwest monsoon Their results show that weak (strong) wind velocities overlie cold (warm) SST, which is the same as Nonaka’s result [16]. Koseki et al [19] used a high-resolution atmospheric circulation model to study the response characteristics of the atmospheric boundary layer to mesoscale ocean eddies in the Kuroshio extension They showed that the spatial patterns of surface wind anomalies and mesoscale SST anomalies are significantly correlated. Ma et al [22] used high-resolution satellite observations to reveal distinct seasonal variations in atmospheric responses to oceanic eddies in the Kuroshio Extension region, characterized by much stronger surface wind speed and heat flux responses in the cold seasons (winter and spring) than in the warm seasons (summer and autumn).
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