The Polar Atmosphere:Forecasts from weather and climate
models
David H. BromwichByrd Polar Research Center, The Ohio State University
Research Urgencies in the Polar RegionsSiena, 23 Sept 2011
Atmospheric changes in the Arctic• Widespread warming of the Arctic:
– Record temperature and melt extent in Greenland in 2010[Box et al., Arctic Report Card, 2010]
– Lowest (or 2nd-lowest) Arctic sea-ice extent reached on 8-9 Sept. 2011
University of Bremen (http://www.iup.uni-bremen.de:8084/amsr)
Ice concentration, 8 Sept. 2011Greenland melt extent in 2005
http://cires.colorado.edu/science/groups/steffen/greenland/melt2005/
Atmospheric changes in the Antarctic• More regional changes:– Warming in the Antarctic
Peninsula and West Antarctica(?)– But lowest Antarctic melt extent
in 2008 & 2009 since 1987 [Tedesco & Monaghan, 2009]
Melt ponds
Breakup of the Larsen B Ice Shelf in 2002[Steig et al., 2009]
Arctic vs Antarctic
• Despite being both “polar”, the Arctic and Antarctic exhibit important differences in their climate and exposure to climate warming
[Bromwich and Wang, 2008]
Numerical models
• The reliability of these models in polar regions (and elsewhere) depends on:– our understanding of the physical processes– our ability to represent them numerically– the availability of observations to constrain the
model
• Models are used:– to monitor/predict/
understand climate change– for weather guidance Source: NOAA
Numerical Models & time scales
Shorter time scales(e.g., days)
Longer time scales(e.g., centuries)
• Numerical Weather Prediction (NWP) models
• Reanalyses (global, regional)
• Global Climate Models (GCMs)
MODELING THE POLAR ATMOSPHERE
Physical processes that need to be optimized for polar regions
• Surface energy balance and heat transfer over sea ice and permanent ice surfaces
• Variable sea ice thickness and snow thickness over sea ice
• Seasonally-varying sea ice albedo• Cloud / radiation interaction • Ice phase microphysics • Turbulence (boundary layer) parameterization
Example: Sea-ice albedo variabilityMay
June
July
August Sept.
Images: Courtesy from D. Perovich
Example: Sea-ice albedo variabilityObservations from the SHEBA experiment (Arctic)
[Perovich et al., 2007]
NUMERICAL WEATHER PREDICTION IN POLAR REGIONS
Challenges for NWP in Polar Regions
• NWP models generate short-term forecasts based on a known initial state of the atmosphere
• The accuracy of the forecasts depends on– the proper representation of physical processes– the amount/distribution of observations used to
initialize the forecasts (data assimilation)• Challenge: the sparsity of observations in high
latitudes (esp. in Antarctica)
Tropospheric observations for NWP• Limited number of radiosonde observations in high latitudes (the Arctic
Ocean and Southern Ocean are virtual data voids)• However, the growing volume of satellite observations used for data
assimilation has greatly improved the performance of NWP models in high latitudes
• Satellite data assimilation remains challenging over ice-covered surfaces
Andersson et al., ECMWF Newsletter, 2007
Arctic and Antarctic stations reporting daily radiosoundings in July 2006
Antarctic AWS network - 2011
Map from AMRC/UW-Madison (http://amrc.ssec.wisc.edu/)
• Expansion of the AWS network in Antarctica since the 1990s
• Provide observations used for:– data assimilation into NWP
models– model evaluation
• Challenges:– maintenance of the network– Surface observations only
NWP in the Arctic• NAM: North American Mesoscale Model
• 12-km grid, 4-day forecasts• Model: Weather Research and Forecasting (WRF) model
• Twice-daily forecasts by the Polar Meteorology Group • 45-km grid, 4-day forecasts; Model: Polar WRF
• NWP in the Arctic becoming increasingly important as (if?) economic activities develop in this part of the world
NAM
“Unfreezing Arctic Assets”, WSJ, 18 Sep. 2010
NWP in the Arcticby the Polar Meteorology Group
24h forecast for 12 UTC 14 Sept 2011Website: http://polarmet.osu.edu/nwp/?model=arctic_wrf
USA
Italy
2m temperature and sea-level pressure 6h total precipitation
NWP in the Antarctic• A dedicated effort:
The Antarctic Mesoscale Prediction Sytem (AMPS)
• Support operations of the US Antarctic Program
• Model: A polar-optimized version of WRF (Polar WRF)
• Grids with resolutions ranging 15km (Antarctica) to 1.6km (McMurdo area)
• Forecasts out to 5 days
McMurdo
AMPS grids
www.mmm.ucar.edu/rt/wrf/amps/
AMPS 24-h forecast (00 UTC 15 Sep 2011)
Antarctic domain (resolution: 20km)
Ant. Peninsula domain (resolution: 5km)
Website: www.mmm.ucar.edu/rt/wrf/amps/
REANALYSES IN POLAR REGIONS
Challenges for reanalyses in Polar Regions
• A reanalysis uses a state-of-the-art NWP model to retrospectively analyze historic observations (e.g., from 1979 onward)
• Challenges:– Global models not “tuned” for high latitudes,
(hence the benefits of regional reanalyses)– Sparsity of observations– Impact of changes in the observations (e.g., from
satellites)
The Antarctic surface mass balancefrom global reanalyses
• Figure: Mean annual Antarctic Precip-minus-Evap (P-E) during 1989-2009 from 5 global reanalyses and one observation-based dataset.
• The reanalyses show various skills at representing the mean Antarctic climate, which itself is known with great uncertainties
Bromwich et al., J. Climate, 2011
mm/yr
Trends in global reanalysesThe Arctic warming
• The magnitude of tropospheric temperature trends in the Arctic varies greatly from one reanalysis to the other.
• Challenge: produce temporally consistent datasets not affected by changes in the observing system (e.g., satellite observations) and suitable for climate change assessment
• Some improvements in the most recent reanalyses thanks to more effective bias correction of satellite radiances
ERA-40 JRA-25NCEP-NCAR
DJF MAM
JJA SON
[Graversen et al., Nature, 2008]
Trends in global reanalysesThe Arctic warming
ERA-40 minus ERA-Interim
Figures from Screen and Simmonds, J. Climate, 2011
Regional reanalysis:The Arctic System Reanalysis (ASR)
Regional reanalysis:The Arctic System Reanalysis (ASR)
• A physically-consistent integration of Arctic and other Northern Hemisphere data.
• Mesoscale model: Polar WRF• High resolution in space (10 km) and time (3 hours),
convenient for synoptic and mesoscale studies• Begins with years 2000-2010 (Earth Observing System)• Assimilation of a wide range of conventional and satellite
observations• Participants:
– Ohio State University - Byrd Polar Research Center (BPRC) and Ohio Supercomputer Center (OSC)
– National Center for Atmospheric Research (NCAR)– Universities of Colorado and Illinois.
Precipitation yearly total 2007ASR vs ERA-Interim
ASR
ERA
ERA-Int
(cm)
GLOBAL CLIMATE MODELS (GCMs) IN POLAR REGIONS
Challenges for GCMs in Polar Regions
• Benchmarking of GCMs in polar regions– Sparse observations, esp. on multi-decadal scales
• Model grid resolution:– IPCC AR4 models: typically 250km horiz.– Ant. Peninsula, Ant. steep coastal slopes: scales < 100km
• Parameterizations of subgrid-scale processes– Optimized for lower latitudes– E.g., the atmospheric boundary layer (very stable over
snow/ice)• Representation of atmosphere-ocean interactions– Annual cycle of sea-ice cover– Climate modes of variability (e.g., SAM, ENSO)
Benchmarking of IPCC AR4 GCMsExample 1: Antarctic temperatures & P-E
• 20th century annual Antarctic temperature trends in the five GCMs are about 2.5-to-5 times larger than observed
• Better agreement between the GCMs and observations for snowfall, although the GCMs differ in their ability to reproduce the magnitude/distribution of snowfall
• Uncertainties in the observations themselves (reconstructed fields)
Ensemble
Observation-based
Five AR4 GCMS
Monaghan et al., GRL, 2008
Benchmarking of AR4 GCMsExample 2: Polar clouds
• Clouds play an important in the moisture/precipitation and energy budget of the Antarctic Ice Sheet
• They are simulated with various skills by GCMs (figure)
• Substantial progress has been made recently in our knowledge of the climatology of Antarctic clouds thanks to observations from active satellite sensors (CloudSat-CALIPSO)
Mean annual cloud fraction (%)
[Bromwich et al., submitted]
Atmospheric modes of variability(Southern Hemisphere)
• The reliability of GCM simulations also depends upon their ability to reproduce the observed modes of atmospheric variability
• These modes influence the temperature and moisture advection onto Antarctica
ENSO teleconnection
Southern Annular Mode(aka Antarctic Oscillation)
SST composites for El Niño and La Niña conditions [X. Yuan, 2004]
El Niño
La Niña
Impact of stratospheric ozone
• The projected changes of the SAM depend, in part, on whether the GCMs include ozone forcing (the SAM is also influenced by greenhouse-gas concentrations)
• The projected changes in ENSO variability are strongly influenced by the coupling between the atmospheric and ocean models, and highly model-dependent.
Figure: Multi-model mean of the regression of the leading EOF of ensemble mean Southern Hemisphere sea level pressure for models with (red) and without (blue) ozone forcing. The thick red line is a 10-year low-pass filtered version of the mean. The grey shading represents the intermodel spread at the 95% confi dence level. [IPCC, 2007]
Atmosphere-ocean interface: Sea ice
• AR4 GCMs exhibit a wide range of sea ice extents
• Excessive sea-ice cover in CCSM4 is due to anomalously strong zonal winds over the Southern Ocean
Antarctic sea-ice extent in CCSM4
Figure: 1980–1999 sea ice distribution simulated by 14 AOGCMs. For each pixel, the figure indicates the number of models that simulate at least 15% of the area covered by sea ice. The red line shows the observed 15% concentration boundaries. [IPCC, 2007]
Sea-ice extent in IPCC AR4 GCMs
March September
observations
[Landrum et al., submitted]
Projected temperature and precipitation changes (IPCC, 2007)
Future climate change simulated by GCMs must be viewed bearing in mind the limitations of these models
Annual surface temperature and precipitation changes between 1980-99 and 2080-99 from the multi-model ensemble A1B projections
[IPCC, 2007]
Concluding remarks• Despite substantial progress made in the
MODELING of the polar atmosphere, further improvements are still needed in current models, esp. in GCMs.
• This effort would/will benefit from the development of an integrated and robust OBSERVING network in both polar regions to:– monitor ongoing changes– help enhance our understanding of
the physical processes at play– and provide input for numerical
models
Leverett Glacier, Transantarctic Mountains. Photo by Paul Thur.