Abstract
Four sequential tropical cyclones generated and developed in the Northwest Pacific Ocean (NWP) in 2014, which had significant impacts on the oceanic environment and coastal regions. Based on a substantial dataset of multiple-satellite observations, Argo profiles, and reanalysis data, we comprehensively investigated the interactions between the oceanic environment and sequential tropical cyclones. Super typhoon Neoguri (2014) was the first typhoon-passing studied area, with the maximum sustained wind speed of 140 kts, causing strong cold wake along the track. The location of the strongest cold wake was consistent with the pre-existing cyclonic eddy (CE), in which the average sea surface temperature (SST) cooling exceeded −5 °C. Subsequently, three tropical cyclones passed the ocean environment left by Neoguri, namely, the category 2 typhoon Matmo (2014), the tropical cyclone Nakri (2014) and the category 5 typhoon Halong (2014), which caused completely different subsequent responses. In the CE, due to the fact that the ocean stratification was strongly destroyed by Neoguri and difficult to recover, even the weak Nakri could cause a secondary response, but the secondary SST cooling would be overridden by the first response and thus could cause no more serious ocean disasters. If the subsequent typhoon was super typhoon Halong, it could cause an extreme secondary SST cooling, exceeding −8 °C, due to the deep upwelling, exceeding 700 m, surpassing the record of the maximum cooling caused by the first typhoon. In the anti-cyclonic eddy (AE), since the first typhoon Neoguri caused strong seawater mixing, it was difficult for the subsequent weak typhoons to mix the deeper, colder and saltier water into the surface, thus inhibiting secondary SST cooling, and even the super typhoon Halong would only cause as much SST cooling as the first typhoon. Therefore, the ocean responses to sequential typhoons depended on not only TCs intensity, but also TCs track order and ocean mesoscale eddies. In turn, the cold wake caused by the first typhoon, Neoguri, induced different feedback effects on different subsequent typhoons.
Highlights
Tropical cyclones (TCs) are strong natural hazards that are generated and developed in the tropical ocean
Compared with super typhoon Neoguri, the Ekman pumping velocity (EPV) induced by typhoon Matmo and Nakri was more dispersed, and the radius was wider than 300 km (Figure 2f–g)
Multi-platform satellite observations revealed the evolutions of sea surface temperature (SST) cooling and chl-a enhancement during the four sequential typhoons, as well as the modulation effects of the mesoscale eddies in the Northwest Pacific Ocean (NWP) on the SST cooling and chl-a enhancement
Summary
Tropical cyclones (TCs) are strong natural hazards that are generated and developed in the tropical ocean. TCs with maximum wind speeds higher than 32.7 m/s in the north-western Pacific are referred to as typhoons, which are important for the local ocean environment [1,2,3], global ocean heat transport [4,5], and kinetic energy budget [6,7]. Air–sea interaction plays an important role in weather and climate change, and the interaction between tropical cyclones and ocean is an important part of air–sea interaction. Ocean response to typhoons has a long history of research, the most significant being the cold wake often seen along the typhoon track due to ocean surface enthalpy fluxes, vertical mixing, and upwelling [8,9,10]. The SST cooling was usually by 1–6 ◦ C [14,15,16], and by more than 10 ◦ C in some extreme cases [17,18], which may have a negative feedback effect on the passing typhoon [19,20,21,22]
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