1 / 30

Spring Onset in the Northern Hemisphere: A Role for the Stratosphere?

Spring Onset in the Northern Hemisphere: A Role for the Stratosphere?. Robert X. Black Brent A. McDaniel School of Earth and Atmospheric Sciences Georgia Institute of Technology, Atlanta, Georgia Walter A. Robinson Department of Atmospheric Sciences

sauda
Download Presentation

Spring Onset in the Northern Hemisphere: A Role for the Stratosphere?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Spring Onset in the Northern Hemisphere:A Role for the Stratosphere? Robert X. Black Brent A. McDaniel School of Earth and Atmospheric Sciences Georgia Institute of Technology, Atlanta, Georgia Walter A. Robinson Department of Atmospheric Sciences University of Illinois at Urbana-Champaign

  2. Zonal average east-west winds (u) for January Stratosphere (polar vortex) Troposphere [Yang & Schlesinger, 1998]

  3. Interannual Variability in Spring Onset: Spring PhenologyCross-correlation between phenodates and late-winter NAO index (D’Odorico et al. 2002)

  4. Interannual Variability in Spring Onset: Lower Tropospheric Temperature over Western ArcticMarch/April 925 hPa geopotential height anomalies4 Cold years 4 Warm years (Overland et al. 2002)

  5. Interannual Variability in Spring Onset: OzoneLate winter AO index vs. spring tropospheric ozone (Lamarque and Hess 2004)

  6. Predictability Variations: Winter vs. Summer (Newman et al. 2003)

  7. Predictability Variations: AO/NAO Persistence

  8. Predictability Variations: Month-to-month persistence Anti-persistence over the North Atlantic during Spring (van den Dool and Livezey 1983)

  9. Stratosphere-Troposphere Coupling: NAM StructureLower Troposphere: AO/NAO variations Stratosphere: Polar vortex variations (Thompson and Wallace 2001)

  10. Stratosphere-Troposphere Coupling: Intraseasonal EvolutionStratospheric precursors to Tropospheric AO/NAO events (Baldwin and Dunkerton 2001)

  11. Stratosphere-Troposphere Coupling: Monthly PredictabilityNAM time series as predictor of surface AO (Baldwin et al. 2003)

  12. Climatological Trend in Stratospheric Polar Vortex Relatively abrupt breakdown of stratospheric polar vortex during Spring (Stratospheric Final Warming)

  13. Considerations • Significant interannual variability in the timing of stratospheric final warming (SFW) events • Thought experiment: Composite 10 hPa zonal wind evolution with respect to SFW timing

  14. Contrast SFW Composite [u] with Seasonal Trend Substantial local sharpening of [u] tendency field Anomalous [u] both prior to and after SFW onset

  15. Considerations • Significant interannual variability in the timing of stratospheric final warming (SFW) events • Thought experiment: Composite 10 hPa zonal wind field with respect to SFW timing & plot • Question: To what extent does the stratospheric trend sharpening extend down to troposphere? • Hypothesis: Interannual variations in SFW timing provide net impact on the troposphere (AO/NAO)

  16. Composites of Winter Sudden Stratospheric Warming Events (Limpasuvan et al. 2004)

  17. Approach • Identify SFW events based upon variation in [u] @ 70N (done for 10 hPa & 50 hPa, respectively) • Calculate 3-D circulation anomalies (deviations from seasonal trend values) for each day in a 41 day window centered on SFW event • Composite together 40 annual anomaly evolutions • Events identified separately in NCEP/NCAR, ERA-40, and Free University Berlin datasets • Primary dataset for compositing: NCEP/NCAR reanalyses for 1958-1997

  18. Initial Assessment: SFW impact upon AO/NAO Negative AO/NAO after SFW onset Positive AO/NAO prior to SFW onset (lag 0)

  19. Composite Anomaly Evolution: Zonal Wind 10 day low-pass filtered data

  20. Composite Anomaly Evolution: Zonal Wind 10 day low-pass filtered data

  21. Composite Circulation Anomaly Change: Zonal-mean Zonal Wind 10 day low-pass filtered data

  22. Composite Anomaly Evolution: 50 hPa Z 10 day low-pass filtered data

  23. Composite Anomaly Evolution: 50 hPa Z 10 day low-pass filtered data

  24. Composite Anomaly Evolution: 1000 hPa Z 10 day low-pass filtered data

  25. Composite Anomaly Evolution: 1000 hPa Z 10 day low-pass filtered data

  26. Composite Circulation Anomaly Change: 1000 hPa Z 10 day low-pass filtered data

  27. Composite Circulation Time Evolution:Total Zonal Wind EP Flux/wave driving 10 day low-pass filtered data

  28. Composite Circulation Time Evolution:Total Zonal Wind EP Flux/wave driving 10 day low-pass filtered data

  29. Summary • Pronounced westerly (easterly) zonal wind anomalies in the high latitude stratosphere in the 2 weeks prior to (after) SFW events • Reflects more rapid breakup of the stratospheric polar vortex compared to climatological trend • Opposing zonal wind anomalies at low latitudes • Stratospheric features extend downward well into the troposphere • Troposphere characterized by persistent +ve (-ve) NAO episodes prior to (following) SFW events

  30. Summary (Continued) • Latter feature consistent with anti-persistence observed by van den Dool and Livezey (1983) • Stratospheric transition is dynamically driven by anomalous upward flux of Rossby wave activity emanating from tropospheric altitudes • SFW events provide new paradigm for studying stratosphere-troposphere dynamical coupling • Better understanding & simulation of SFW events may provide an avenue for enhancing medium range forecast skill during spring onset (?)

More Related