Net Modulation of Upper Ocean Thermal Structure by Typhoon Kalmaegi (2014)

Zhang, Han; Wu, Renhao; Chen, Dake; Liu, Xiaohui; He, Hui; Tang, Youmin; Ke, Daoxun; Shen, Zheqi; Li, Junde; Xie, Juncheng; Tian, Di; Ming, Jie; Fu, Liu; Zhang, Dongna; Zhang, Wenyan

doi:10.1029/2018jc014119

Cited by 64 publications

(81 citation statements)

References 68 publications

(96 reference statements)

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“…The numerical model used in this study was a three-dimensional version of the Price-Weller-Pinkel model (3DPWP) [54,55], which has been used successfully in previous studies to simulate and understand the physical processes involved in the oceanic response to a TC [15][16][17]22,[56][57][58]. The model domain used here spans 1200 km in the across-track direction and 5600 km in the along-track direction, with a horizontal resolution of 8 km and a vertical resolution of 10 m with the ocean depth of 1450 m. The time resolution is 120 s. The model starts from rest, and the initial temperature and salinity were set to be horizontally homogeneous using the average profiles from Station 2 during UTC 00:00 on 14 October to UTC 00:00 on 16 October for Sarika and during UTC 00:00 on 18 October to UTC 00:00 on 20 October for Haima (see Figure 2).…”

Section: Typhoons Sarika and Haimamentioning

confidence: 99%

“…The near-inertial current normally decays within 5-20 inertial periods and propagates both horizontally and vertically in the ocean [20,21]. The near-inertial current is accompanied by alternative upwelling and downwelling (near-inertial pumping) [22], which is asymmetric with a rapid transition from a maximum in the downwelling phase to a maximum in the upwelling phase, followed by a gradual transition to the next downwelling maximum [23,24]. The horizontal and vertical propagation of the near-inertial current results in wave dispersion and propagation of kinetic energy [10,16,25,26], which can also generate super-inertial internal waves such as double-inertial frequency (2f ) waves [27,28] that contribute to the energy cascade toward dissipation.…”

Section: Introductionmentioning

confidence: 99%

“…The sea surface temperature (SST) cooling was usually by 1-6 • C [2,4,[31][32][33][34][35], and by more than 10 • C in some extreme cases [36,37]. Owing to the rightward (or leftward) bias of the current response, the temperature response is also usually biased to the right side (or left side) of the TC track in the Northern (or Southern) Hemisphere [15,22]. Besides mixing, the vertical advection (upwelling and downwelling) and horizontal advection can also modulate the oceanic temperature structure.…”

Section: Introductionmentioning

confidence: 99%

“…Besides mixing, the vertical advection (upwelling and downwelling) and horizontal advection can also modulate the oceanic temperature structure. In general, the subsurface warm anomaly can be strengthened or weakened by upwelling or downwelling [15,22,38], and the effect of horizontal advection depends on the current speed and horizontal temperature gradient [22]. The vertical advection mainly influences the subsurface and deeper ocean, as Argo data reveal that upwelling contributes an average of 15% of the cooling in the near-surface layer (10-30 m), 84% in the subsurface layer (30-250 m), and 94% in the deep layer (250-600 m) during the period of 0.5-2.5 days after the passage of a typhoon [39].…”

Section: Introductionmentioning

confidence: 99%

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Ocean Response to Successive Typhoons Sarika and Haima (2016) Based on Data Acquired via Multiple Satellites and Moored Array

Zhang

Liu

et al. 2019

Remote Sensing

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Tropical cyclones (TCs) are natural disasters for coastal regions. TCs with maximum wind speeds higher than 32.7 m/s in the north-western Pacific are referred to as typhoons. Typhoons Sarika and Haima successively passed our moored observation array in the northern South China Sea in 2016. Based on the satellite data, the winds (clouds and rainfall) biased to the right (left) sides of the typhoon tracks. Sarika and Haima cooled the sea surface ~4 and ~2 °C and increased the salinity ~1.2 and ~0.6 psu, respectively. The maximum sea surface cooling occurred nearly one day after the two typhoons. Station 2 (S2) was on left side of Sarika’s track and right side of Haima’s track, which is studied because its data was complete. Strong near-inertial currents from the ocean surface toward the bottom were generated at S2, with a maximum mixed-layer speed of ~80 cm/s. The current spectrum also shows weak signal at twice the inertial frequency (2f). Sarika deepened the mixed layer, cooled the sea surface, but warmed the subsurface by ~1 °C. Haima subsequently pushed the subsurface warming anomaly into deeper ocean, causing a temperature increase of ~1.8 °C therein. Sarika and Haima successively increased the heat content anomaly upper than 160 m at S2 to ~50 and ~100 m°C, respectively. Model simulation of the two typhoons shows that mixing and horizontal advection caused surface ocean cooling, mixing and downwelling caused subsurface warming, while downwelling warmed the deeper ocean. It indicates that Sarika and Haima sequentially modulated warm water into deeper ocean and influenced internal ocean heat budget. Upper ocean salinity response was similar to temperature, except that rainfall refreshed sea surface and caused a successive salinity decrease of ~0.03 and ~0.1 psu during the two typhoons, changing the positive subsurface salinity anomaly to negative

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Section: Typhoons Sarika and Haimamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Ocean Response to Successive Typhoons Sarika and Haima (2016) Based on Data Acquired via Multiple Satellites and Moored Array

Zhang

Liu

et al. 2019

Remote Sensing

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“…Furthermore, our previous works (e.g., [2,50,[88][89][90][91][92][93]) indicate thatoceanic thermohaline and dynamic features play an important role in upper ocean response to a single or sequential typhoons based on multiple observation data and model simulations. However, these works were mainly in the marginal sea (the South China Sea) and we may further follow the study of this paper, and study how some special topographic features such as with many islands or straits influences the structure of the oceanic response to typhoons in the future.…”

Section: Future Workmentioning

confidence: 96%

Response of Coastal Water in the Taiwan Strait to Typhoon Nesat of 2017

Yang

Tian

et al. 2019

Water

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The oceanic response of the Taiwan Strait (TWS) to Typhoon Nesat (2017) was investigated using a fully coupled atmosphere-ocean-wave model (COAWST) verified by observations. Ocean currents in the TWS changed drastically in response to significant wind variation during the typhoon. The response of ocean currents was characterised by a flow pattern generally consistent with the Ekman boundary layer theory, with north-eastward volume transport being significantly modified by the storm. Model results also reveal that the western TWS experienced the maximum generated storm surge, whereas the east side experienced only moderate storm surge. Heat budget analysis indicated that surface heat flux, vertical diffusion, and total advection all contributed to changes in water temperature in the upper 30 m with advection primarily affecting lower depths during the storm. Momentum balance analysis shows that along-shore volume acceleration was largely determined by a combined effect of surface wind stress and bottom stress. Cross-shore directional terms of pressure gradient and Coriolis acceleration were dominant throughout the model run, indicating that the effect of the storm on geostrophic balance was small. This work provides a detailed analysis of TWS water response to typhoon passage across the strait, which will aid in regional disaster management.

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Vertical and horizontal variations in phytoplankton chlorophyll a in response to a looping super typhoon

Chen,

Zhao,

Han

2024

Limnology & Oceanography

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Previous studies suggested that the increase in surface chlorophyll a (Chl a) is due to nutrient upwelling or to the upward mixing of the subsurface Chl a maximum layer under the influence of tropical cyclones, while often ignoring the influence of the subsurface Chl a minimum layer and horizontal advection on Chl a. In this study, we show the important roles of the upward mixing of the subsurface Chl a minimum layer, horizontal advection, as well as the upwelling of the subsurface Chl a maximum layer, taking a looping super typhoon “Saola” in the northwest Pacific in August 2023 as an example. The temporal and spatial changes of Chl a and its physical properties were investigated by combining satellite, Argo, reanalysis, and model data. The results indicate that the combined effects of the upwelling of the subsurface Chl a maximum layer caused by wind stress curls and concurrent near‐surface wind mixing were responsible for the surface Chl a increase in the looping area during the typhoon, while the 13% increase in the depth‐integrated Chl a after the typhoon is mainly due to the nutrients brought by upwelling and subsequent biochemical processes. In the edge area affected by the typhoon, the surface Chl a decrease during the typhoon was mainly due to the upward mixing of the subsurface Chl a minimum layer (the effect of upwelling in this area is relatively weak). Furthermore, the horizontal advection led to a continuous surface Chl a decrease in the edge area after the typhoon. These findings could enhance understanding of Chl a dynamics post‐tropical cyclones, aiding marine ecosystem prediction.

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Net Modulation of Upper Ocean Thermal Structure by Typhoon Kalmaegi (2014)

Cited by 64 publications

References 68 publications

Ocean Response to Successive Typhoons Sarika and Haima (2016) Based on Data Acquired via Multiple Satellites and Moored Array

Ocean Response to Successive Typhoons Sarika and Haima (2016) Based on Data Acquired via Multiple Satellites and Moored Array

Response of Coastal Water in the Taiwan Strait to Typhoon Nesat of 2017

Vertical and horizontal variations in phytoplankton chlorophyll a in response to a looping super typhoon

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