Coupled Ocean–Atmosphere Response to Seasonal Modulation of Ocean Color: Impact on Interannual Climate Simulations in the Tropical Pacific

The ability to use remotely sensed ocean color data to parameterize biogenic heating in a coupled ocean–atmosphere model is investigated. The model used is a hybrid coupled model recently developed at the Earth System Science Interdisciplinary Center (ESSIC) by coupling an ocean general circulation...

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Bibliographic Details
Published in:Journal of climate 2007-01, Vol.20 (2), p.353-374
Main Authors: Ballabrera-Poy, J., Murtugudde, R., Zhang, R.-H., Busalacchi, A. J.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Atmosphere
Atmospheric models
Biological and medical sciences
Chlorophylls
Climate cycles
Climate models
Climatology. Bioclimatology. Climate change
Crash cushions
Earth, ocean, space
El Nino
Equatorial dynamics
Exact sciences and technology
External geophysics
Fundamental and applied biological sciences. Psychology
Marine
Meteorology
Ocean-atmosphere interaction
Oceans
Optical properties
Plankton
Scale models
Sea water ecosystems
Simulation
Simulations
Solar radiation
Synecology
Thermoclines
Transcriptional regulatory elements
Turbidity
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Summary:The ability to use remotely sensed ocean color data to parameterize biogenic heating in a coupled ocean–atmosphere model is investigated. The model used is a hybrid coupled model recently developed at the Earth System Science Interdisciplinary Center (ESSIC) by coupling an ocean general circulation model with a statistical atmosphere model for wind stress anomalies. The impact of the seasonal cycle of water turbidity on the annual mean, seasonal cycle, and interannual variability of the coupled system is investigated using three simulations differing in the parameterization of the vertical attenuation of downwelling solar radiation: (i) a control simulation using a constant 17-m attenuation depth, (ii) a simulation with the spatially varying annual mean of the satellite-derived attenuation depth, and (iii) a simulation accounting for the seasonal cycle of the attenuation depth. The results indicate that a more realistic attenuation of solar radiation slightly reduces the cold bias of the model. While a realistic attenuation of solar radiation hardly affects the annual mean and the seasonal cycle due to anomaly coupling, it significantly affects the interannual variability, especially when the seasonal cycle of the attenuation depth is used. The seasonal cycle of the attenuation depth interacts with the low-frequency equatorial dynamics to enhance warm and cold anomalies, which are further amplified via positive air–sea feedbacks. These results also indicate that interannual variability of the attenuation depths is required to capture the asymmetric biological feedbacks during cold and warm ENSO events.
ISSN:0894-8755
1520-0442
DOI:10.1175/jcli3958.1