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Key Questions to Answer on Storm Simulation
Xiangdong Zhang
International Arctic Research CenterUniversity of Alaska Fairbanks, Fairbanks, AK 99775, USA
Jing Zhang, and Jeremy R. Krieger Geophysical Institute
University of Alaska Fairbanks, Fairbanks, AK 99775, USA
Arctic System Model Workshop, August 6-7, 2007
Why ASM?
1. Capture high resolution features that GCM could not resolve well.
Why ASM?
1. Capture high resolution features that GCM could not resolve well.
Why ASM?
1. Capture high resolution features that GCM could not resolve well.
2. Capture realistic physical processes or feedbacks that GCM could not simulate well.
Why Storm?
1. Primary weather system and could have high impact in mid- and high-latitudes.
2. Enhancing atmosphere-sea ice-ocean interactions and may leave fingerprints on climate variability and change.
Zhang, J., et al. 2007: Modeling Study of an Arctic Storm Process and Associated Atmosphere-Sea Ice-Ocean Interactions by Using a Coupled Regional Model. under revision.
Yang et al. 2004
Why Storm?
1. Primary weather system and could have high impact in mid- and high-latitudes.
2. Enhancing atmosphere-sea ice-ocean interactions and may leave fingerprints on climate variability and change.
3. Storm activity has intensified in Arctic and storm track has shifted poleward, highly associated with large scale climate variability and change.
Trends and variability: Arctic CAI
The integrative index CAI (Cyclone Activity Index) represents a combination of information of cyclone trajectory count, duration and intensity.
Zhang, X., et al. 2004: Climatology and interannual variability of Arctic cyclone activity, 1948-2002. J. Climate, 17, 2300-2317.
Relationship to mid-latitudes: Poleward shift
• Both the intensity and trajectory count show increasing trends;
• The increase was dramatically amplified around 1990.
There are more and stronger cyclones originating southern 60N entering the Arctic, particularly around 1990.
Zhang, X., et al. 2004: Climatology and interannual variability of Arctic cyclone activity, 1948-2002. J. Climate, 17, 2300-2317.
Flux Exchanges
Atmosphere (MM5)
Land Ocean & Sea Ice
Arctic MM5: Regional Weather & Climate Model
One more step forward:
Zhang, J., et al. 2007: Modeling Study of an Arctic Storm Process and Associated Atmosphere-Sea Ice-Ocean Interactions by Using a Coupled Regional Model. under revision.
taking atmosphere-sea ice-ocean coupling process into account
Flux Exchanges
Atmosphere (MM5)
Land Ocean & Sea Ice
Arctic MM5: Regional Weather & Climate Model
One more step forward:
Dynamic Downscaling
Glacier Mass BalanceZhang, J., et al. 2007: Response of glaciers in northwestern North America to future climate change: an atmosphere/glacier hierarchical modeling approach. Annals of Glaciology, 46, 283-290.
taking atmosphere-sea ice-ocean coupling process into account
Zhang, J., et al. 2007: Climate downscaling for estimating glacier mass balance in Northwestern North America: Validation with USGS index glacier. Geophy. Res. Lett., submitted.
Arctic MM5 Storm Simulation: Model Domain
Arctic MM5 Storm Simulation: Initial Condition
Arctic MM5 Storm Simulation: 2m Air Temperature
Arctic MM5 Storm Simulation: Cloudiness
Arctic MM5 Storm Simulation: Ocean Temperature
Arctic MM5 Storm Simulation: Sea Ice Thickness
Flux Exchanges
Atmosphere (WRF)
Land Ocean & Sea Ice
Transition: Arctic MM5 Arctic WRF
WRF Simulation: Model Domain
WRF Simulation: Surface Pressure
WRF Simulation: 2 m Air Temperature
WRF Simulation: 2 m Mixing Ratio
WRF Simulation: 10 m Windspeed