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Ray Bell Supervisors – Prof. Pier Luigi Vidale , Dr. Kevin Hodges and Dr. Jane Strachan

Tropical Cyclones and Climate Change – PhD Project Results from HiGEM High Resolution Climate Model. Ray Bell Supervisors – Prof. Pier Luigi Vidale , Dr. Kevin Hodges and Dr. Jane Strachan. MO TCWG – 21st Jul. PhD questions.

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Ray Bell Supervisors – Prof. Pier Luigi Vidale , Dr. Kevin Hodges and Dr. Jane Strachan

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  1. Tropical Cyclones and Climate Change – PhD ProjectResults from HiGEM High Resolution Climate Model Ray Bell Supervisors – Prof. Pier Luigi Vidale, Dr. Kevin Hodges and Dr. Jane Strachan MO TCWG – 21st Jul

  2. PhD questions • Will there be a change in TC activity (location, intensity, frequency, lifetime, structure) with climate change? • How does this change depend on resolution? • How well are the governing mechanisms represented in climate models and how does resolution affect their representation? • What is the role of teleconnections - Possible ENSO changes on NAtl TC activity? • [What is the role of coupling with the ocean?]

  3. Models NH May - Nov HadGAM N96 -135km HiGEM N144 - 90km NUGAM N216 - 60km

  4. HiGEM CTRL TC variability 150 years => 5x30. Min, Max, and Avg at each point

  5. HiGEM CTRL TC activity compared to Obs • Lack of re-curving in NWPAC - SSTs in the NWPAC?

  6. HiGEM CTRL TC frequency • Reduced ATL activity – Cold bias? - ATL known to the most sensitive basin to SST (Emanuel, 2008) • Max intensity ~cat 3 (50m/s +) • Obsfrom http://www.wunderground.com/blog/JeffMasters/archive.html?year=2011&month=04 Using IBTrACS (not same criteria as tracking) • * att is attain 850hPa wind speed >20m/s dataset

  7. Change in track densities with increased CO2

  8. Change in track densities with increased CO2

  9. Change in frequency • ATL shows largest decrease • EPAC shows an increase at 2xCO2 • NIND shows an increase • - attain 850hPa wind speed 20m/s gives a + change in TC freq. Suggesting largest decrease of TCs from weaker storms * att is attain 850hPa wind speed >20m/s dataset

  10. Change in intensity (850hPa wspeed)

  11. Regional change of 850hPa wspeed

  12. Change in duration

  13. Regional Change in duration

  14. Change in structure 100 most intense TCs at most intense Earth relative winds Below 35oN NH Avg 30 yr ctrl 4xCO2 2xCO2 10o radius 850hPa

  15. Future work • Attribution of change in TC activity - SST – Local vs. Remote changes in each basin - Wind shear • Changes in SH • ENSO influence on NATL activity - compare IBTrACS and re-analysis to HiGEM present day simulation and future climates) • Model HiGEM SSTs on HadGAM to compared different model resolutions

  16. Questions/Comments/Suggestions ? References Bengtsson, L., Hodges, K. I., and Esch, M. (2007). Tropical cyclones in a T159 resolution global climate model: comparison with observations and re-analysis. Tellus A, 59, 396–416. Hodges, K.I. (1995) Feature tracking on a unit sphere Mon. Weath. Rev. 123, pp 3458-3465.

  17. Previous studies • Uncertainties in future dynamical and thermodynamical changes due to anthropogenic warming in the tropics. Change in precursors (e.g. AEWs...) • Current trends and attribution Natural variability (Pielkeet al, 2005) vs. Climate change (Webster et al, 2005) Limitations in the quality and availability of data (Kossinet al, 2007) • Theory (Emanuel, 1987) and high resolution modelling studies (Knutson et al. 2004; Oouchieet al. 2006) predict TCs will become more intense. • Little theory explaining the change in TC frequency - likely to become less frequent in a warmer world.

  18. Previous studies • Global increase in TC intensities of 2-11% (surface wind speed). (3-21% decrease in central pressure) by 2100 (A1B scenario) (Knutson et al, 2010) • Decrease in globally averaged frequency of TCs by 6-34% - Weakening of the tropical circulation (Increase in dry static stability) (Sugi, 2002) - Increase in q* causes larger Xm (moist S in middle of troposphere and that of the BL), therefore takes longer to moisten mid-trop where intensification can occur (Emanuel, 2008) • More robust decrease in the SH – smaller increase in SST and increase wind shear (Vecchi, 2007; Zhao et al, 2009) • Increase of 20% in precipitation rate within 100km of the storms centre (Knutson et al, 2010) • Higher resolution models needed to pick up a warming related intensification (<60km) (Bengtssonet al, 2007)

  19. Previous studies (Knutson et al, 2010) Large Regional Uncertainties

  20. TRACK Hodges (1995); Bengstssonet al. (2007) • T42 ξ850 (0o-60oN)– Reduce noise. Comparison of different spatial resolution data • Minimum lifetime of 2 days and no constraint on the minimum displacement distance. Capture more of TC lifecycle • Cyclogenesis (0-20oN over land, 0-30oN over ocean) • Coherent vertical structure and warm core • Max T63 vor at each level from 850hPa to 250hPa • Intensity threshold T63 ξ850 > 6x10-5 s-1, ξ850 – ξ200 > 6x10-5 s-1 , for at least 1 day (4 x 6hr) • Associate full res data with tracks • Wind speed must attain 20m/s at 850hPa (change in slightly more intense TCs) • Statistical packages • Investigating multiple level warm core testing and cyclogenesis over the ocean – hope to cut out monsoon depressions

  21. Jane’s previous work

  22. Change in Atl track densities

  23. Change in genesis densities

  24. Change in lysis densities

  25. Change in structure 100 most intense TCs at most intense System relative winds Below 35oN Avg 30 yr ctrl 4xCO2 2xCO2 10o radius 850hPa

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