Strong Ocean–Atmosphere Interactions during a Short-Term Hot Event over the Western Pacific Warm Pool in Response to El Niño

A short-term hot event with a very high sea surface temperature (SST ≥ 30°C) occurred in the western Pacific warm pool during November 2006. The interactions between this ocean hot event, atmospheric convection, and large-scale dynamics are studied using satellite observations, buoy measurements, ai...

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Bibliographic Details
Published in:Journal of climate 2016-05, Vol.29 (10), p.3841-3865
Main Authors: Chen, Guixing, Qin, Huiling
Format: Article
Language:English
Subjects:
Air-sea flux
Anomalies
Atmosphere
Atmospheric convection
Atmospheric dynamics
Atmospheric models
Buoy measurements
Climate
Climate models
Climate prediction
Cloud clusters
Convective activity
Convective instability
Convective systems
Dynamic stability
Dynamics
Easterlies
El Nino
El Nino phenomena
Enthalpy
Equatorial waves
Heat content
High seas
Instability
Lower troposphere
Marine
Mixed layer
Ocean mixed layer
Ocean mixing
Oceanic convection
Oceans
Satellite observation
Satellites
Sea surface
Sea surface temperature
Sea surface temperature anomalies
Steering
Surface temperature
Trade winds
Tropical easterlies
Troposphere
Water vapor
Water vapour
Wave propagation
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Summary:A short-term hot event with a very high sea surface temperature (SST ≥ 30°C) occurred in the western Pacific warm pool during November 2006. The interactions between this ocean hot event, atmospheric convection, and large-scale dynamics are studied using satellite observations, buoy measurements, air–sea fluxes analysis, and global reanalysis. It is shown that SST variation and deep convection over the western Pacific behave like a remote response to the El Niño warm SST anomaly in the central Pacific that induces westward-moving atmospheric convection and equatorial waves. The large-scale subsidence associated with propagating convection not only promotes high SSTs in the western Pacific through establishing cloud-free conditions and increasing heat content in a thin ocean mixed layer, but also produces convective instability through capping substantial water vapor in the lower troposphere. Under the precondition of convective instability and the steering of tropical easterlies, some convective systems propagate coherently from the central to western Pacific and intensify. In particular, new cloud clusters are dynamically attracted to the warmest oceans with maximum atmospheric instability. The enhanced convective activity then transfers oceanic energy into the atmosphere, strengthens upper-ocean mixing, and returns the positive SST anomalies to more typical values. In such a coupled system, synoptic-scale convective activities at an interval of 5–8 days are selectively amplified and thus are filtered to an intraseasonal (20–30-day) oscillation, depending on the phase of the hot event over the western Pacific. The observed evidence has implications for the predictability of short-term climate, and it offers critical information for validating the coupled ocean–atmosphere dynamics in climate models.
ISSN:0894-8755
1520-0442
DOI:10.1175/JCLI-D-15-0595.1