Alleviating tropical Atlantic sector biases in the Kiel climate model by enhancing horizontal and vertical atmosphere model resolution: climatology and interannual variability

We investigate the quality of simulating tropical Atlantic (TA) sector climatology and interannual variability in integrations of the Kiel climate model (KCM) with varying atmosphere model resolution. The ocean model resolution is kept fixed. A reasonable simulation of TA sector annual-mean climate,...

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Bibliographic Details
Published in:Climate dynamics 2018-04, Vol.50 (7-8), p.2605-2635
Main Authors: Harlaß, Jan, Latif, Mojib, Park, Wonsun
Format: Article
Language:English
Subjects:
Annual variations
Atmosphere
Atmospheric circulation
Atmospheric models
Atmospheric research
Climate
Climate models
Climate variability
Climatology
Computer simulation
Convergence zones
Earth and Environmental Science
Earth Sciences
Equator
Equatorial winds
Frequency dependence
Geophysics/Geodesy
Interannual variability
Intertropical convergence zone
Momentum
Momentum transport
Ocean circulation
Ocean models
Ocean-atmosphere interaction
Oceanography
Orography
Resolution
Sea surface
Sea surface temperature
Seasonal variability
Seasonal variation
Simulation
Spring
Surface temperature
Surface wind
Thermal structure
Thermocline
Tropical climate
Upwelling
Wind
Wind structure
Winds
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Summary:We investigate the quality of simulating tropical Atlantic (TA) sector climatology and interannual variability in integrations of the Kiel climate model (KCM) with varying atmosphere model resolution. The ocean model resolution is kept fixed. A reasonable simulation of TA sector annual-mean climate, seasonal cycle and interannual variability can only be achieved at sufficiently high horizontal and vertical atmospheric resolution. Two major reasons for the improvements are identified. First, the western equatorial Atlantic westerly surface wind bias in spring can be largely eliminated, which is explained by a better representation of meridional and especially vertical zonal momentum transport. The enhanced atmospheric circulation along the equator in turn greatly improves the thermal structure of the upper equatorial Atlantic with much reduced warm sea surface temperature (SST) biases. Second, the coastline in the southeastern TA and steep orography are better resolved at high resolution, which improves wind structure and in turn reduces warm SST biases in the Benguela upwelling region. The strongly diminished wind and SST biases at high atmosphere model resolution allow for a more realistic latitudinal position of the intertropical convergence zone. Resulting stronger cross-equatorial winds, in conjunction with a shallower thermocline, enable a rapid cold tongue development in the eastern TA in boreal spring. This enables simulation of realistic interannual SST variability and its seasonal phase locking in the KCM, which primarily is the result of a stronger thermocline feedback. Our findings suggest that enhanced atmospheric resolution, both vertical and horizontal, could be a key to achieving more realistic simulation of TA climatology and interannual variability in climate models.
ISSN:0930-7575
1432-0894
DOI:10.1007/s00382-017-3760-4