Changes of temperature and bio‐optical properties in the South China Sea in response to Typhoon Lingling, 2001

Shang, Shuo; Li, Li; Sun, Fei; Wu, Jingyu; Hu, Chuanmin; Chen, Dewen; Ning, Xin; Qiu, Yun; Zhang, Caiyun; Shang, Songhao

doi:10.1029/2008gl033502

Cited by 108 publications

(91 citation statements)

References 17 publications

(35 reference statements)

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“…7b), after which Hagibis crept westward to the coastline southeast of Vietnam. Comparing the present results with those of previous studies (Lin et al 2003, Shi & Wang 2007, Gierach & Subrahmanyam 2008, Shang et al 2008, we determined that the EPV was quite large in the case of Typhoon Hagibis (Table 2); this large value probably reflected the fact that Hagibis passed close to the equator (at 10°N), and the Coriolis parameter was about half that of other typhoons, which were tracked at approximately 20°N. Thus, the potential EPV calculated from Eq.…”

Section: Physical Mechanismsupporting

confidence: 71%

“…In the East China Sea, Typhoon Meari induced a 3-fold increase in primary production, contributing 3.8% of the annual new production (Siswanto et al 2008). For the South China Sea (SCS), it was also estimated that, on average, 30-fold increases in surface chl a concentrations were triggered by Typhoons Kai-Tak (2000) (Lin et al 2003) and Lingling (2001) (Shang et al 2008). Typhoon Kai-Tak (2000) alone and typhoons occurring during the entire year induced from about 2 to 4% and 20 to 30% of the SCS's annual new primary production, respectively (Lin et al 2003).…”

Section: Introductionmentioning

confidence: 99%

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Strong enhancement of chlorophyll a concentration by a weak typhoon

Sun¹,

Yang²,

Xian³

et al. 2010

Mar. Ecol. Prog. Ser.

122

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Recent studies demonstrate that chlorophyll a (chl a) concentrations in ocean surface waters can be significantly enhanced due to typhoons. The present study investigated chl a concentrations in the middle of the South China Sea (SCS) from 1997 to 2007. Only the Category 1 (minimal) Typhoon Hagibis (2007) had a notable effect on chl a concentrations. Typhoon Hagibis had a strong upwelling potential due to its location near the equator, and the forcing time of the typhoon (> 82 h) was much longer than the geostrophic adjustment time (~63 h). The higher upwelling velocity and the longer forcing time increased the depth of the mixed-layer, which consequently induced a strong phytoplankton bloom that accounted for about 30% of the total annual chl a concentration in the middle of the SCS. Induction of significant upper ocean responses can be expected if the forcing time of a typhoon is long enough to establish strong upwelling.

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Section: Physical Mechanismsupporting

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Strong enhancement of chlorophyll a concentration by a weak typhoon

Sun¹,

Yang²,

Xian³

et al. 2010

Mar. Ecol. Prog. Ser.

122

View full text Add to dashboard Cite

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“…For example, the maximum upwelling depth caused by Typhoon Lingling (2001) was observed to be only 300 db (Shang et al, 2008), and the maximum upwelling depth was less than 200 db in the vicinity of Bermuda (Black & Dickey, 2008). Third, the upwelling of the thermocline had an obvious establishment process.…”

Section: Upper Ocean Responses To Namtheunmentioning

confidence: 99%

Ocean Responses to Typhoon Namtheun Explored with Argo Floats and Multiplatform Satellites

et al. 2012

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Argo salinity and temperature profiles, along with other sea surface measurements, were used to explore the impacts of Typhoon Namtheun (2004) on the ocean. Namtheun took local enthalpy heat from the sea (0.39-0.7 × 10 8 J m −2 ), cooled the sea surface water as a result of vertical mixing (maximum 3-4°C) and produced heavy precipitation over the sea (100-180 mm). During this time, the vast latent heat released (2.6-4.4 × 10 8 J m −2 ) by the precipitation made a larger contribution to the typhoon's energy budget than the local air-sea enthalpy flux. In the upper ocean, the oceanic responses can be separated into two sub-processes, the fast spin-up accompanied by one-dimensional vertical mixing and the slow spin-down accompanied by the convergence of surface water. From Argo profiles on 28 July, it can be seen that the typhoon-induced surface mixing broke down the seasonal thermocline (approximately 20 db) within one day. In addition, the shallower (<200 db) convergence of the sea surface fresh water as a result of precipitation also made the post-typhoon water fresher (0.04 (practical salinity scale used)). In the deep ocean, the rapid upwelling at the top of the permanent thermocline suggests that the fast spin-up is a barotropic mechanism, probably gravity pressure. During the slow spin-down stage, the upwelling signal propagated downward (approximately 2 m h −1 ) from the shallow water to the deep ocean for about 10 days; this was a baroclinic process. The baroclinic mechanism was more effective in maintaining a cyclonic eddy than in maintaining an inertial wave, and the low sea surface height anomaly and upwelling lasted much longer than the inertial oscillation (>20 days as opposed to approximately 10 days). This change in vertical structure and long-term upwelling could have impacts on the ocean environment and even on the short-term climate.RÉSUMÉ [Traduit par la rédaction] Nous nous sommes servis des profils de salinité et de température Argo, de pair avec d'autres mesures de la surface de la mer, pour explorer les répercussions du typhon Namtheun (2004) sur l'océan. Namtheun a pris de la chaleur enthalpique locale de la mer (0.39-0.7 × 10 8 J m −2 ), a refroidi l'eau de la surface de la mer par suite d'un mélange vertical (maximum 3°-4°C) et a produit de fortes précipitations au-dessus de la mer (100-180 mm). Durant ce temps, l'importante quantité de chaleur latente (2.6-4.4 × 10 8 J m −2 ) relâchée par les précipitations a apporté une plus grande contribution au bilan énergétique du typhon que le flux enthalpique air-mer local. Dans la couche supérieure de l'océan, les réponses océaniques peuvent être divisées en deux sous-processus, la surgyration rapide accompagnée d'un mélange vertical unidimensionnel et la dégyration lente accompagnée de la convergence d'eau de surface. Sur les profils Argo du 28 juillet, on peut voir que le mélange en surface produit par le typhon a brisé la thermocline saisonnière (approximativement 20 db) à l'intérieur d'une journée. De plus, la convergence moins profo...

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“…Using remote sensing observations, there were many studies showing that under stormy conditions, sea surface Chl-a increases are attributed to the enhanced nutrient supplies caused by the upwelling and vertical mixing [4,[13][14][15]39]. Strong typhoon winds may induce massive entrainment of air bubbles into the water column through the wave breaking; these bubbles have a spectral effect on ocean reflectance, and therefore, the bubble entrainment may affect the estimation accuracy of surface Chl-a concentration from remote sensing observations [40].…”

Section: Discussionmentioning

confidence: 99%

“…Since the forcing of tropical cyclone winds can induce strong ocean mixing and upwelling, nutrients in the sub-surface can be brought into the ocean surface layer, enhancing photosynthesis and boosting primary productivity at the ocean surface [4,[13][14][15]. After the passage of tropical cyclones, sufficient light provides favorable conditions for the growth of phytoplankton in the upper ocean.…”

Section: Introductionmentioning

confidence: 99%

Quantification of Typhoon-Induced Phytoplankton Blooms Using Satellite Multi-Sensor Data

et al. 2018

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Using satellite-based multi-sensor observations, this study investigates Chl-a blooms induced by typhoons in the Northwest Pacific (NWP) and the South China Sea (SCS), and quantifies the blooms via wind-induced mixing and Ekman pumping parameters, as well as pre-typhoon mixed-layer depth (MLD). In the NWP, the Chl-a bloom is more correlated with the Ekman pumping than with the other two parameters, with an R 2 value of 0.56. In the SCS, the wind-induced mixing and Ekman pumping have comparable correlations with the Chl-a increase, showing R 2 values of 0.4~0.6. However, the MLD exhibits a negative correlation with the Chl-a increase. A multi-parameter quantification model of the Chl-a bloom strength achieves better results than the single-parameter regressions, yielding a more significant R 2 value of 0.80, and a lower regression rms of 0.18 mg·m −3 in the SCS, and the R 2 value in the NWP is also improved compared with the single-parameter regressions. The multi-parameter quantification model of Chl-a blooms is more accurate in the SCS than in the NWP, due to the fact that nutrient profiles in the NWP are uniform from surface to a deep depth (300 m). Thus, the Chl-a blooms are more correlated with the upper ocean dynamical processes in the SCS where a shallower nutricline is found.

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Changes of temperature and bio‐optical properties in the South China Sea in response to Typhoon Lingling, 2001

Cited by 108 publications

References 17 publications

Strong enhancement of chlorophyll a concentration by a weak typhoon

Strong enhancement of chlorophyll a concentration by a weak typhoon

Ocean Responses to Typhoon Namtheun Explored with Argo Floats and Multiplatform Satellites

Quantification of Typhoon-Induced Phytoplankton Blooms Using Satellite Multi-Sensor Data

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