A Coupled Ocean Physics‐Biology Modeling Study on Tropical Instability Wave‐Induced Chlorophyll Impacts in the Pacific

Tian, Feng; Wang, Xiujun

doi:10.1029/2018jc013992

Cited by 16 publications

(12 citation statements)

References 69 publications

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“…Compared with FILT (Figure S8), the SST is cooling by 0.1–0.2 °C in CTRL during La Niña event, demonstrating the Chl TIW effect induces a cooling during La Niña event. This result is also consistent with previous ocean general circulation model study (Tian et al, ).…”

Section: Resultssupporting

confidence: 94%

“…Additionally, the HCM can well simulate coherent structure of SST and Chl at TIW scale (Figures a–d); that is, high Chl concentration corresponds to cold SST phase, whereas low Chl concentration corresponds to warm SST phase (Figures c–d). The amplitude of Chl TIW is 0.05–0.1 mg/m 3 , which is in good agreement with estimates from observations (Tian et al, ).…”

Section: Resultssupporting

confidence: 91%

“…High and low chlorophyll concentrations are associated with cold and warm phases of TIWs‐induced perturbations in SST ( SST TIW ), with the amplitude of Chl TIW reaching 0.05 mg/m 3 (Evans et al, ; Gorgues et al, ; Legeckis et al, ; Menkes et al, ; Strutton et al, ; Yoder et al, ). Furthermore, presence of Chl TIW influences the redistribution of solar radiation in the upper ocean and consequently weakens the intensity of TIW itself (Tian et al, ). In particular, penetrative solar radiation induced by Chl TIW changes ocean stratification, with the reduced baroclinic conversion rate between eddy available potential and eddy kinetic energy (EKE).…”

Section: Introductionmentioning

confidence: 99%

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A Positive Feedback Onto ENSO Due to Tropical Instability Wave (TIW)‐Induced Chlorophyll Effects in the Pacific

Tian

Wang

2019

Geophysical Research Letters

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Tropical instability waves (TIWs) induce large physical and biological perturbations, which have a feedback onto the tropical Pacific climate and ecosystem. However, the extent to which TIW‐induced chlorophyll perturbations (ChlTIW) can influence El Niño–Southern Oscillation (ENSO) remains unknown. Here we used a hybrid‐coupled model to investigate the ChlTIW effect on ENSO. Two experiments are conducted, one with the ChlTIW effect being represented in the control run (CTRL) and other with the ChlTIW effect being purposely excluded by filtering out ChlTIW signals (FILT). Results show that the amplitude of ENSO is increased by 27% in CTRL compared to FILT. ChlTIW tends to modulate the penetrative solar radiation in the upper ocean, acting to weaken the intensity of TIWs. Then, the weakened TIWs lead to a reduction in the equatorward meridional heat transport and consequently less warming effect on the cold tongue. Therefore, La Niña conditions tend to be intensified, and ENSO amplitude is increased.

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Section: Resultssupporting

confidence: 94%

Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

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A Positive Feedback Onto ENSO Due to Tropical Instability Wave (TIW)‐Induced Chlorophyll Effects in the Pacific

Tian

Wang

2019

Geophysical Research Letters

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“…The model used in this study is a coupled ocean physics‐biogeochemistry model (Tian et al, ; Wang et al, ; Wang, Le Borgne, et al, ; Zhang et al, ), which consists of an ocean general circulation model (OGCM) and a biogeochemistry model. It is also the ocean component of the hybrid‐coupled model for atmosphere‐ocean and biogeochemistry (HCM‐AOPB), which is employed in ZH19.…”

Section: Model Data Used and Experimentsmentioning

confidence: 99%

“…Previous studies documented basic performances of the coupled ocean physics‐biogeochemistry model, which shown that the model could well simulate mean state, seasonal cycle, and interannual variability in the physical and biological fields (Tian et al, ; Wang et al, , ; Zhang et al, ). Figure shows the response of chlorophyll to ENSO for the observations and model forced by observed and reanalysis atmospheric forcing.…”

Section: Overview Of the Model Simulationsmentioning

confidence: 99%

Effects on Ocean Biology Induced by El Niño‐Accompanied Positive Freshwater Flux Anomalies in the Tropical Pacific

Tian

Wang

2020

JGR Oceans

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The El Niño and Southern Oscillation (ENSO) can induce large perturbations in freshwater flux (FWF, defined as precipitation minus evaporation) and ocean ecosystem in the tropical Pacific. However, how El Niño-induced FWF can affect the tropical Pacific ecosystem (e.g., chlorophyll) is still unknown. Here, a series of ocean-only experiments are performed using a coupled ocean-physical biogeochemistry model forced by prescribed climatological wind stress. Interannual FWF anomalies observed during the 1997-1998 El Niño event are imposed onto the ocean model in the tropical Pacific, and the related positive FWF anomalies are specified to be varying in its intensity, and the corresponding sensitivity experiments are performed to examine the ocean ecosystem response. In general, chlorophyll increases with the intensities of the El Niño-induced positive FWF anomalies at a certain strength but decreases when the positive FWF forcing is underrepresented (e.g., specified to be its half intensity). Additionally, chlorophyll in the eastern tropical Pacific keeps almost steady during the increasing stage of the El Niño-induced interannual FWF forcing and then rapidly increases after the peak stage of the FWF forcing. The phytoplankton budget and diagnostic analyses are conducted to understand the behavior of chlorophyll in response to varying intensities of FWF forcing. Chlorophyll response to varying intensities of FWF forcing depends on the iron concentration in the mixed layer, suggesting that the ocean ecosystem response may be shifted from one regime to another when FWF forcing reaches a certain intensity. These results offer insights into biophysical interactions and chlorophyll-induced feedback effects on ENSO.Plain Language Summary Chlorophyll is used to represent changes in phytoplankton biomass, and its variability is significantly modulated by multiscale physical processes. In the tropical Pacific, ENSO can induce large perturbations in freshwater flux (FWF) and ocean ecosystem. Given that FWF forcing affects sea surface salinity and buoyancy flux, it is reasonable to ask the following question: Can El Niño-induced FWF forcing affect the tropical Pacific ecosystem (e.g., phytoplankton and chlorophyll)? Here we examine the effect of FWF forcing on ocean biology using a coupled physics-biogeochemistry model, in which FWF forcing is explicitly represented with varying intensity. Results suggest that chlorophyll concentration in the eastern equatorial Pacific tends to increase in response to El Niño-accompanied positive FWF anomalies. However, a regime shift can occur when the FWF forcing intensity is underrepresented (e.g., specified to be its half intensity), with chlorophyll concentration tending to decrease instead. The behavior of chlorophyll in response to varying FWF forcing intensities is regulated by the iron concentration in the mixed layer, suggesting that the ocean ecosystem response may be shifted from one regime to another when FWF forcing reaches a certain intensity. These results offer insights into bi...

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Role of Nanotechnology in Medicine: Opportunities and Challenges

Ejidike,

Ogunleye,

Bamigboye

et al. 2024

Environmental Science and Engineering

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A Coupled Ocean Physics‐Biology Modeling Study on Tropical Instability Wave‐Induced Chlorophyll Impacts in the Pacific

Cited by 16 publications

References 69 publications

A Positive Feedback Onto ENSO Due to Tropical Instability Wave (TIW)‐Induced Chlorophyll Effects in the Pacific

A Positive Feedback Onto ENSO Due to Tropical Instability Wave (TIW)‐Induced Chlorophyll Effects in the Pacific

Effects on Ocean Biology Induced by El Niño‐Accompanied Positive Freshwater Flux Anomalies in the Tropical Pacific

Role of Nanotechnology in Medicine: Opportunities and Challenges

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