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Table of Contents

  1. Introduction: AIACC: Climate Change and Conservation Planning
    1. Chapter1: Evidence for climate change
      1. Slide 1: Introduction: the evidence for anthropogenic climate change
      2. Slide 2: Climate variation
      3. Slide 3 : Climate change
      4. Slide 4: What are we looking for?
      5. Slide 5: Sources of data - instrumental
      6. Slide 6: Temperature
      7. Slide 7: Palaeoclimate reconstruction from proxy data
      8. Slide 8: Palaeoclimatological time scale
      9. Slide 9: Proxy data sources: Ice cores
      10. Slide 10: Proxy data sources: Dendroclimatology
      11. Slide 11: Proxy data sources: Oceanic sediments
      12. Slide 12: Proxy data sources: Other
      13. Slide 13: The role of climate models
      14. Slide 14: Evidence for change
      15. Slide 15: Thermal indicators: Glacial melting
      16. Slide 16: Thermal indicators: Sea ice
      17. Slide 17: Thermal indicators: permafrost
      18. Slide 18: Thermal indicators: Sea level change
      19. Slide 19: Thermal indicators: Sea temperatures
      20. Slide 20: Is oceanic circulation changing?
      21. Slide 21: The greenhouse effect
      22. Slide 22: Climate change forcings
      23. Slide 23: Greenhouse gases: methane
      24. Slide 24: Greenhouse gases: nitrous oxide
      25. Slide 25: Greenhouse gases: carbon dioxide
      26. Slide 26: Greenhouse gases: others
      27. Slide 27: Aerosols
      28. Slide 28: Sulphates and nitrates
      29. Slide 29:Thermal indicators: global air temperature
      30. Slide 30: Changes in precipitation
      31. Slide 31: Climate change indicators: extreme weather
      32. Slide 32: Conclusions?
      33. Slide 33:Test yourself
      34. Slide 34: Links to other chapters
    2. Chapter 2: Global circulation models
      1. Chapter 4: Biodiversity responses to past changes in climate
        1. Chapter 5: Adaptation of biodiversity to climate change
          1. Chapter 6: Approaches to niche-based modelling
            1. Chapter 7: Ecosystem function modelling
              1. Chapter 8: Climate change implications for conservation planning
                1. Chapter 9: The economic costs of conservation response options for climate change
                  1. Course Resources
                    1. Practical: Conservation for Climate Change
                      1. Tests to Assess your Understanding
                        1. How to run a GAM model in R

                          Slide 10: Proxy data sources: Dendroclimatology

                          Duration: 00:00:50


                          The pattern of growth of trees is laid down within their structure, providing a high-resolution (annual) picture of climatic variables in the Holocene.

                          Much can be deduced from growth bands - the thickness corresponds to the favourability of climatic conditions (light, temperature, rainfall, windspeed) (Bradley,1985; Fritts, 1976).

                          The density of the bands says much about the growing season (latewood is much denser than earlywood) (Schweingruber et al., 1978).

                          Isotopic analysis of the bands can also give us information about the climatic conditions. (Epstein et al., 1976).

                          By studying a number of trees in an area of a similar age, a statistically sound analysis of conditions can be obtained.


                          Bradley, R.S., 1985. Quaternary Palaeoclimatology: Methods of Palaeoclimatic Reconstruction. Unwin Hyman, London, 472pp.

                          Epstein, S., Yapp, C.J. & Hall, J.H., 1976. The determination of the D/H ratio of non-exchangeable hydrogen in cellulose extracted from aquatic and land plants. Earth Planet. Sci. Lett., 30, pp. 241-251.

                          Fritts, H.C., 1976. Tree rings and climate. Academic Press, London.

                          Schweingruber, F.H., Fritts, H.C., Bräker, O.U., Drew, L.G. & Schär, E., 1978. The X-ray technique as applied to dendroclimatology. Tree Ring Bull., 38, pp. 61-91.