Hans von Storch:

1. MPI reunion, 28. August 2006 Hans von Storch: Die Veränderung unserer heimischen Stürme – jetzt und später im 21ten Jahrhundert

2. In the early 1990s, MPI spokespeople told the public ... • Storms are getting more severe. • The reason is global warming. • The evidence is given by storms counts. • Dynamical explanation:in a warmer world there is more „fuel“ for storms, which aregetting more energetic.

3. The evidence was poor … • Key problem: data availability and homogeneity; better observations describe more extreme cases. • Cultural construction – man is deteriorating climate; one of the apocalyptic riders is – storms. • „News“ about deteriorating heimische Sturmtätigkeit sells well – drama & consistency with pre-scientific knowledge. • Two options – either join the bandwagon, which supports a politically correct worldview – or open-mindedly examine the claims, which is the task of science.

4. 10-yearly sum of events with winds stronger than 7 Bft in Hamburg

5. Time series of frequency of stormy days in Kullaberg (south-western Sweden), number of days per year with wind speed V≥21 m/s, after Blomgren (1999). Damaging storm event

6. Counting storms in weather maps – steady increase of NE Atlantic storms since the 1930s ….

8. 99%iles of annual geostrophic wind speeds for a series of station triangles in the North Sea regions and in the Baltic Sea region. Alexandersson et al., 2002

9. Stormcount 1958-2001 Change of # Bft 8/year t ≥ T t ≤ T Weisse et al., J. Climate, 2005

10. Stockholm Lund Time series of pressure-based storminess indices derived from pressure readings in Lund (blue) and Stockholm (red). From top to bottom: Annual number of pressure observations below 980 hPa (Np980), annual number of absolute pressure differences exceeding 16 hPa/12 h (NDp/Dt), Intra-annual 95-percentile and 99-percentile of the pressure differences (P95 and P99) in units of hPa. From Bärring and von Storch, 2005 (GRL)

11. Testign the “more fuel” argument • Simulation with climate model exposed to estimated volcanic, solar and GHG forcing, year 1550-2000. • Model is Atmosphere-Ocean GCM ECHO-G with Atmospheric Model ECHAM4 (T30) (~3.75°x 3.75°  ~300 km x 300 km) and Ocean Model HOPE-G (T43) (~2.8°x 2.8°  ~200 km x 200 km) • Number of strong wind events per season (wind at 10 m;  8 Bft, gales) were counted. Fischer-Bruns et al., 2005: Clim Dyn.

12. Temp & storm count: No correlation in pre-industrial period Warming and Storms in the N Atlantic N Atlantic Fischer-Bruns et al., 2005 (11-yr running means)

13. Storm frequency per season A2 – pre-industrial industrial – pre-industrial DJF JJA Fischer-Bruns et al., 2005

14. How is the extratropical storm climate variability linked to hemispheric temperature variations? • During pre-industrial times, no obvious link between extra-tropical storminess and hemispheric mean temperatures exist. • In the scenarios describing the effect of increasing GHG concentrations, storminess and temperature develop in parallel. • If we believe the GCM scenario for the end of the 21st century and assume a linear development, then we should not be able to detect a change now and in the near future.

15. What do we have to tell the public? • Anthropogenic climate change is real. • Anthropogenic climate change is presently detectable in temperature and related parameters. • A detectable change will occur in other variables at a later time. • No significant changes in heimischer Sturmtätigkeit is detectable; An increase by 10-20% in strong wind speeds is plausible for the end of the 21st century. For the coming decades this change is cmall compard ot the natural variability.