1. 3. Climate Change 3.1 Observations 3.2 Theory of Climate Change 3.3 Climate Change Prediction 3.4 The IPCC Process

2. 2 3.1 Observations Need to consider: Instrumental climate record of the last century or so Recent changes in greenhouse gases and other quantities Acknowledgement: Steve Arnold (University of Leeds, UK)

3. 3 Important Questions Concerning the Climate Record How much is the world warming? Is the recent warming unusual? How rapidly is climate changing compared to earlier changes? Have precipitation and atmospheric moisture changed? Are atmospheric/oceanic circulations changing? Has climate variability (e.g., extremes) changed?

4. 4 Observed Climate Variables Temperature (global mean, regional, diurnal range, upper air...) Precipitation, humidity, cloud cover Snow cover Sea-ice thickness and extent Natural modes (El Nino, North Atlantic Oscillation, Atlantic Multidecadal Oscillation) Climate extremes

5. 5 Use of ‘Anomalies’ Anomalies are changes relative to some particular reference period used to emphasise positive and negative excursions around a long-term mean

6. 6 Global Mean Land-Surface Temperatures Temperature anomalies (difference from 1961- 1990 mean) Surface temperature trend ~0.05 O C / decade since 1850. Urban “heat island” effect is negligible (~0.006 O C / decade) Differences between compilations arise from weighting of observation density

7. 7 Global Mean Land-surface and Sea Surface Temperatures Recent land warming dominated by NH continents Ocean warming slower 20 th -century T Change ~0.7±0.2 O C –Compare 0.45 O C estimated by IPCC in 1995. Land SST

8. Trends 8 http://youtu.be/e0vj-0imOLw

9. 9 Spatial Pattern of Surface Temperature Changes 1901-2005 1975-2005 Grey areas: not enough data White crosses: significant trend

10. 10 Summary of Surface Temperature Changes In the 20 th century there has been a consistent large- scale warming of the land and ocean surface. Rate of warming appears to be accelerating Some regional details can be explained by atmospheric circulation changes

11. 11 Upper Air Temperatures Weather balloons (radiosondes) –T at discrete levels –Difficulties with changes in instruments Satellite (Microwave Sounding Unit – MSU and stratospheric Sounding Unit - SSU) since 1979 –T over broad regions –Problems with orbit drift, calibration, etc. -> spurious T trends

12. 12 Upper Air Temperatures Stratosphere cooling at > 0.5 O C/decade Volcanic eruptions cool troposphere and heat stratosphere Troposphere up to ~10km has warmed at slightly faster rate than surface since 1950s. Stratosphere cooled markedly since 1979.

13. 13 Changes in the Cryosphere Snow cover Sea-ice extent Mountain glaciers - Average Arctic temperatures have increased at almost twice the global average rate in past 100 years. WMO International Polar Year 2007-2008 www.ipy.org

14. 14 Observed Northern Hemisphere Snow Cover TOP Annual snow-cover extent decreased by 10% since 1966 Mostly accounted for by spring/summer since 1980s BOTTOM Annual snow cover anomalies correlate with T (dashed line)

15. Observed Northern Hemisphere Sea-Ice Extent http://svs.gsfc.nasa.gov/vis/a000000/a003400 /a003456/AMSR_E_SeaIce_to_09_14_2007_ 512x288.m1vhttp://svs.gsfc.nasa.gov/vis/a000000/a003400 /a003456/AMSR_E_SeaIce_to_09_14_2007_ 512x288.m1v 15

16. 16 Observed Northern Hemisphere Sea-Ice Extent Summer minimum Arctic sea ice extent

17. NASA Goddard Space Flight Center (orange line shows average minimum ice extent (for 1979-2010 period). 2012 has lowest sea ice extent in more than 30 years. Observed Northern Hemisphere Sea-Ice Extent

18. 18 Observed Mountain Glacier Length 169 glacier length records Glacier retreat is worldwide

19. 19 Summary of Observed Cryospheric Changes Consistency of cryospheric changes and temperature changes NH snow cover correlates well with spring temperature changes Reduced sea-ice extent consistent with increases in spring temperatures Small changes in Arctic winter ice, despite large changes in winter T Major retreat of glaciers consistent with 20 th - century T changes

20. 20 Precipitation Wetter: East North and South America, Eurasia Drier: Sahel, S Africa, Mediterranean, S Asia More rain, less snow in northern regions Increased frequency of heavy precipitation

21. 21 Precipitation Wetter: East North and South America, Eurasia Drier: Sahel, S Africa, Mediterranean, S Asia More rain, less snow in northern regions Increased frequency of heavy precipitation Beware of the AMO!

22. Precipitation Increases in amounts of very heavy precipitation (1958-2007) 22 The map shows percent increases in the amount falling in very heavy precipitation events (defined as the heaviest 1 percent of all daily events) from 1958 to 2007 for each region. There are clear trends toward more very heavy precipitation for the nation as a whole, and particularly in the Northeast and Midwest (updated from Groissman et al,2004)

23. 23 Atmospheric/Oceanic Circulations (El Nino) Occurrence of strong El Ninos may be higher since 1980s But significance is low due to strong contribtion of natural variability

24. 24 Atmospheric/Oceanic Circulations (NAO) North Atlantic Oscillation (NAO) is a measure of circulation patterns in the NH Positive index implies warmer Europe Greater occurrence of positive indices since 1980s NAO trending towards negative values recently. Difficult to separate natural variability and long-term change http://www.cgd.ucar.edu/cas/jhurrell/indices.html

25. 25 Climate Extremes (extreme temperatures) Trends in days/decade 1951- 2003 (relative to 1961-1990). 10 th percentile 90 th percentile

26. 26 Climate Extremes (heatwaves)

27. 27 Climate Extremes (precipitation) Contribution from ‘very wet’ days (95 th precentile) to total decadal precipitation.

28. 28 Sea-level Rise Annual average global mean sea level Coastal tide gauges Reconstructed Satellite altimetry

29. Sea-level Rise 29

30. 30 Changes in Greenhouse Gases