Evolution of an anticyclonic eddy southwest of Taiwan

Zu, Tingting; Wang, Dongxiao; C, Yan; Belkin, Igor M.; Zhuang, Wei; Chen, Ju

doi:10.1007/s10236-013-0612-6

Cited by 55 publications

(37 citation statements)

References 39 publications

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“…The TAE, on the contrary, dwells locally near the Taiwan coast for about 35 days and therefore shows the shortest propagation distance (Table 1). This result agrees with the case study in 2006 that the TAE had stayed where it was formed for over 1 month and dissipated locally (Zu et al, 2013).…”

Section: Journal Of Geophysical Research: Oceanssupporting

confidence: 92%

“…Trajectories of the LCE and LWE shown in Figures a and z verify this assessment. Although anticyclonic and cyclonic eddies are observed to the southwest of Taiwan in any month of the year (Nan, Xue, et al, ; Zu et al, ), these eddies, neither occurring in fixed time frames nor following similar patterns and trajectories, fail to meet the criteria for periodic eddies.…”

Section: Resultsmentioning

confidence: 99%

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Periodic Mesoscale Eddies in the South China Sea

Chu

Chen

2020

JGR Oceans

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Although numerous mesoscale eddies are observed in the South China Sea (SCS), a comprehensive study that focuses on periodic eddies has not yet been reported. Periodic eddies are a type of eddies that occur nearly annually in fixed time frames with similar patterns and trajectories. On the basis of in situ and satellite observations, this paper reports a periodic anticyclonic eddy in the western SCS (the Western SCS Anticyclonic Eddy, WAE) and elucidates the underlying processes responsible for its generation and evolution. The WAE is a seasonal phenomenon modulated by the Asian monsoon and basin-scale circulation. Usually, the WAE generates around 112°E, 14°N in February-March, induced by the cyclonic gyre in the northern SCS associated with the winter monsoon. The WAE occupies the western SCS for 5 months and finally dissipates in July due to the reversal of the monsoon and thus the circulation transition. The WAE shows important interannual variations associated with large-scale climate variation, and the Niño-3.4 index could be a potential predictor for its interannual variation. Finally, we summarize 13 periodic eddies in the SCS, including those unreported by previous studies. The period eddies in the SCS exhibit an inverse "L" shape vortex train structure along the western boundary and around the 17°N section, with an anticyclonic "phase" in summer and a cyclonic "phase" in winter. This study provides new knowledge for periodic eddies in the SCS and will benefit targeted observations of periodic eddies.Plain Language Summary Some mesoscale eddies in the ocean are observed to occur nearly annually, we here call them periodic eddies. Due to high occurrence rates, those periodic eddies have profound impacts on local physics, fishery, biology, and air-sea interaction. This study first reports a periodic anticyclonic eddy in the western South China Sea from in situ and satellite observations. By eddy reoccurrence rate, we then summarized all periodic eddies in the SCS. These eddies form the mean state of the mesoscale eddy field in the SCS. This study provides new knowledge for periodic eddies in the SCS and it also carries implications for future studies of periodic eddies in other regions.

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Section: Journal Of Geophysical Research: Oceanssupporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Periodic Mesoscale Eddies in the South China Sea

Chu

Chen

2020

JGR Oceans

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“…Mesoscale eddies are active in the NSCS due to wind stress curl (Qu, ; Wang, Chen, et al, ), Kuroshio current loops (Jia et al, ; Zu et al, ), and the intrusion of western Pacific water masses (Hu et al, ; Wu & Chiang, ). Previous studies have investigated the spatiotemporal distribution, properties, motions, and structures of mesoscale eddies in the NSCS (Chen et al, ; He et al, ; Lin, Dong, et al, ; Wang et al, ; Xiu et al, ; Xie et al, ; Zhang et al, ).…”

Section: Introductionmentioning

confidence: 99%

Features of Slope Intrusion Mesoscale Eddies in the Northern South China Sea

Lin

Mao

et al. 2020

JGR Oceans

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Some mesoscale eddies intrude over the continental slope in the northern South China Sea, supporting cross‐shelf matter transport. We investigated the characteristics, the intruding tracks and formation mechanisms, of slope intrusion mesoscale eddies using satellite altimeter data and model outputs. In total, 36 and 22 slope intrusion anticyclonic and cyclonic eddies (SAEs/SCEs) are found, respectively. Slope intrusion eddies have longer lifetimes (~58 days), smaller size (~110 km), and greater eddy kinetic energy and vorticity compared to ordinary eddies but are more unstable and more easily deformed during their life cycles. The statistical results show that more slope intrusion eddies are generated during winter than other seasons. It is found that slope intrusion eddies mainly propagate westward/northwestward, and southwestward along the continental slope and shelf. Eddy intrusions occur mainly near the Dongsha Islands, east of Hainan, and north of the Xisha Islands. SAEs continue to propagate onshore after arrival at the continental slope, while SCEs dissipate more quickly. Using mooring data, we found that eddy‐ambient flow interaction could cause the differences between SAEs and SCEs around the Dongsha Islands. Energy conversion was analyzed in these three regions using numerical products. During intrusion, eddies lose eddy kinetic energy and ambient flows gain energy.

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“…The causes of mesoscale eddies may be revealed to be the bathymetry anomaly (Sangra et al, 2005) or shedding from strong currents such as the Gulf Stream and the Kuroshio (Hurlburt and Thompson, 1980;Li et al, 1998;Hetland et al, 1999;Zu et al, 2013). When the Kuroshio flows over the Luzon Strait, a meander sometimes forms and the mesoscale eddies may be shed from the unstable meander and propagate westward into the SCS (Li et al, 1998;Wang et al, 2000;Yang et al, 2000;Li et al, 2002;Su et al, 2002;Jia and Liu, 2004;Yuan et al, 2006;Zhang et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Wang et al (2015) pointed out that there are mainly two paths of the mesoscale eddy's westward propagation: one is the along the North South China Sea (NSCS) continental slope, and the other is across the mid-basin from the Philippines moving westward. Along the NSCS continental slope, both the topography and the slope current contribute to the mesoscale eddy propagation (Chow et al, 2008;Wang et al, 2008;Zu et al, 2013). Much of the research has discussed the interaction between the mesoscale eddy and the topography based on ideal numerical experiments (Smith and O'Brien, 1983;Jacob et al, 2002;Sutyrin et al, 2003;Wei and Wang, 2009).…”

Section: Introductionmentioning

confidence: 99%

The topography effect on the sudden deceleration of the mesoscale eddy propagation speed around the Dongsha Islands in northern South China Sea

Yang¹,

Xing

Wang³

et al. 2016

Aquatic Ecosystem Health & Management

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Based on satellite altimeter data, it was found that the mesoscale eddy propagates along the continental slope in northern South China Sea. When the mesoscale eddy passed the Dongsha Islands, the propagation speed clearly slowed down. Additionally, the radius increased and strength decreased when the mesoscale eddy touched the Dongsha Islands. Using the analytic expression for the speed of the center of an isolated eddy, it was found that the sudden slowdown of the zonal propagation speed was accompanied by the sudden decrease of the meridional topography gradient, which was the main reason for the slowdown of the propagation speed.

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Evolution of an anticyclonic eddy southwest of Taiwan

Cited by 55 publications

References 39 publications

Periodic Mesoscale Eddies in the South China Sea

Periodic Mesoscale Eddies in the South China Sea

Features of Slope Intrusion Mesoscale Eddies in the Northern South China Sea

The topography effect on the sudden deceleration of the mesoscale eddy propagation speed around the Dongsha Islands in northern South China Sea

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