Composite of Typhoon‐Induced Sea Surface Temperature and Chlorophyll‐a Responses in the South China Sea

Wang, Yuntao

doi:10.1029/2020jc016243

Cited by 43 publications

(56 citation statements)

References 64 publications

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“…The decrease in SST is a well-known phenomenon associated with typhoons; in comparison, the typhoon-induced variation in chlorophyll concentration is much more complex and varies by case. Increased chlorophyll concentrations are found in 70 % of typhoons in the South China Sea (Wang, 2020) and 18 % of typhoons in the northwest Pacific Ocean (Lin, 2012). These satellite-derived observations of increased surface chlorophyll may be due to enhanced nutrient flux into surface waters from either vertical mixing or enhanced upwelling reaching beyond the nutricline (Zhang et al, 2018), or as shown here, simply mixing of phytoplankton biomass in the DCM throughout the mixed layer (Fig.…”

Section: Discussionsupporting

confidence: 68%

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A limited effect of sub-tropical typhoons on phytoplankton dynamics

et al. 2021

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Abstract. Typhoons are assumed to stimulate primary ocean production through the upward mixing of nutrients into the ocean surface. This assumption is based largely on observations of increased surface chlorophyll concentrations following the passage of typhoons. This surface chlorophyll enhancement, occasionally detected by satellites, is often undetected due to intense cloud coverage. Daily data from a BGC-Argo profiling float revealed the upper-ocean response to Typhoon Trami in the northwest Pacific Ocean. Temperature and chlorophyll changed rapidly, with a significant drop in sea surface temperature and a surge in surface chlorophyll associated with strong vertical mixing, which was only partially captured by satellite observations. However, no net increase in vertically integrated chlorophyll was observed during Typhoon Trami or in its wake. In contrast to the prevailing dogma, the result shows that typhoons likely have a limited effect on net primary ocean production. Observed surface chlorophyll enhancements during and immediately following typhoons in tropical and subtropical waters are more likely to be associated with surface entrainment of deep chlorophyll maxima. Moreover, the findings demonstrate that remote sensing data alone can overestimate the impact of storms on primary production in all oceans. Full understanding of the impact of storms on upper-ocean productivity can only be achieved with ocean-observing robots dedicated to high-resolution temporal sampling in the path of storms.

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Section: Discussionsupporting

confidence: 68%

“…4a and b). Additionally, the wind stress increased before the arrival of the typhoon, resulting in ahead-of-eye cooling and mixing that has been shown to take place a few days earlier (Glenn et al, 2016;Wang, 2020).…”

Section: Discussionmentioning

confidence: 99%

A limited effect of sub-tropical typhoons on phytoplankton dynamics

et al. 2021

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“…TC-induced breaking and unbreaking surface waves also contribute to turbulence in the upper ocean and deepening of the mixed layer (He and Chen, 2011;Toffoli et al 2012;Aijaz et al 2017;Stoney et al 2017;Zhang et al 2018a, b). The wave-breaking-induced acceleration transfers momentum from surface waves to surface currents and also contributes to sediment transport 2020). Non-breaking surface wave-induced mixing in numerical model improves the simulations of sea surface temperature and TC track (Guan and Zhao 2014;Li et al 2014;Aijaz et al 2017;Stoney et al 2017).…”

Section: Figmentioning

confidence: 94%

“…TC-induced mixing, enhanced terrestrial runoff and resuspension are considered three major processes that contribute to the increased nutrient concentrations and subsequent primary production in the euphotic layer (Chen et al 2003). The chlorophyll-a reaches its peak three days after nitrate peak after a TC (Pan et al 2017), and TC-induced phytoplankton blooms usually last for two to three weeks (Babin et al 2004;Chen and Tang 2012;Foltz et al 2015;Wang 2020).…”

Section: Biological Responsementioning

confidence: 99%

Upper ocean response to tropical cyclones: a review

Zhang

et al. 2021

Geosci. Lett.

100

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Tropical cyclones (TCs) are strong natural hazards that are important for local and global air–sea interactions. This manuscript briefly reviews the knowledge about the upper ocean responses to TCs, including the current, surface wave, temperature, salinity and biological responses. TCs usually cause upper ocean near-inertial currents, increase strong surface waves, cool the surface ocean, warm subsurface ocean, increase sea surface salinity and decrease subsurface salinity, causing plankton blooms. The upper ocean response to TCs is controlled by TC-induced mixing, advection and surface flux, which usually bias to the right (left) side of the TC track in the Northern (Southern) Hemisphere. The upper ocean response usually recovers in several days to several weeks. The characteristics of the upper ocean response mainly depend on the TC parameters (e.g. TC intensity, translation speed and size) and environmental parameters (e.g. ocean stratification and eddies). In recent decades, our knowledge of the upper ocean response to TCs has improved because of the development of observation methods and numerical models. More processes of the upper ocean response to TCs can be studied by researchers in the future.

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“…The concentration of Chl-a in the coastal sea surface of the Beibu Gulf in Guangxi exhibited strong seasonal changes, with the following ranking being apparent: summer > autumn > spring and winter (Figure 12). The Chl-a concentration in summer and autumn was mainly affected by the climate [49,50]. In summer, the Beibu Gulf receives abundant rainfall.…”

Section: Temporal Variation Of Chl-amentioning

confidence: 99%

Retrieval of Chlorophyll-a Concentrations in the Coastal Waters of the Beibu Gulf in Guangxi Using a Gradient-Boosting Decision Tree Model

et al. 2021

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Remote sensing for the monitoring of chlorophyll-a (Chl-a) is essential to compensate for the shortcomings of traditional water quality monitoring, strengthen red tide disaster monitoring and early warnings, and reduce marine environmental risks. In this study, a machine learning approach called the Gradient-Boosting Decision Tree (GBDT) was employed to develop an algorithm for estimating the Chl-a concentrations of the coastal waters of the Beibu Gulf in Guangxi, using Landsat 8 OLI image data as the image source in combination with field measurements of Chl-a concentrations. The GBDT model with B4, B3 + B4, B3, B1 − B4, B2 + B4, B1 + B4, and B2 − B4 as input features exhibited higher accuracy (MAE = 0.998 μg/L, MAPE = 19.413%, and RMSE = 1.626 μg/L) compared with different physics models, providing a new method for remote sensing inversion of water quality parameters. The GBDT model was used to study the spatial distribution and temporal variation of Chl-a concentrations in the coastal sea surface of the Beibu Gulf of Guangxi from 2013 to 2020. The results showed a spatial distribution with high concentrations in nearshore waters and low concentrations in offshore waters. The Chl-a concentration exhibited seasonal changes (concentration in summer > autumn > spring ≈ winter).

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Composite of Typhoon‐Induced Sea Surface Temperature and Chlorophyll‐a Responses in the South China Sea

Cited by 43 publications

References 64 publications

A limited effect of sub-tropical typhoons on phytoplankton dynamics

A limited effect of sub-tropical typhoons on phytoplankton dynamics

Upper ocean response to tropical cyclones: a review

Retrieval of Chlorophyll-a Concentrations in the Coastal Waters of the Beibu Gulf in Guangxi Using a Gradient-Boosting Decision Tree Model

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