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Spatial variation in autumn leaf color

Spatial variation in autumn leaf color. Matt Hinckley EDTEP 586 Autumn 2003. Preview. Introduction Background Initial model Methods Results Data, maps, graph Discussion Evidence for claim Revision of model. Introduction: background.

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Spatial variation in autumn leaf color

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  1. Spatial variation in autumn leaf color Matt Hinckley EDTEP 586 Autumn 2003

  2. Preview • Introduction • Background • Initial model • Methods • Results • Data, maps, graph • Discussion • Evidence for claim • Revision of model

  3. Introduction: background • Leaves change color in the fall when they lose their chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall

  4. Introduction: background • Leaves change color in the fall when they lose their chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall

  5. Introduction: background • Leaves change color in the fall when they stopmaking chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall

  6. Introduction: background • Leaves change color in the fall when they stopmaking chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall • Factors: • Light, temperature, precipitation

  7. Introduction: background • Leaves change color in the fall when they stopmaking chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall • Factors: • Light, temperature, precipitation ?

  8. Introduction: background • Leaves change color in the fall when they stopmaking chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall • Factors: • Light, temperature, precipitation ?

  9. Introduction: background • Leaves change color in the fall when they stopmaking chlorophyll • Altitudinal succession mirrors latitudinal succession • Does this principle hold true in this case? • Trees “know” when it’s fall • Factors: • Light, temperature, precipitation Definitely changes by altitude in the Cascades ?

  10. Introduction: initial model Spatial variability Leaf color When leaves fall off

  11. Introduction: initial model Correlation Causal Spatial variability Leaf color Temp. When leaves fall off Precip.

  12. Introduction: initial model Correlation Causal Spatial variability Adiabatic cooling Leaf color Temp. ? When leaves fall off Precip. Light Adiabatic cooling

  13. Introduction: initial model Correlation Causal Elevation Spatial variability Adiabatic cooling Leaf color Temp. ? When leaves fall off Precip. Light Adiabatic cooling

  14. Introduction: assumptions • Trees across the sample area will have leaves that can be observed on them • Most problematic assumption: high elevation deciduous trees had lost all leaves • Conducting observations ≥ 1 week apart would be OK • It was not – leaves change fast, so only one observation was conducted • I would be able to control for tree species

  15. Methods • Driving the Puget Sound area • Digital photography • Image analysis • Quantification of color • GIS analysis of quantitative data • Mapping • Spatial interpolation

  16. Methods • Driving the Puget Sound area • Digital photography • Image analysis • Quantification of color • GIS analysis of quantitative data • Mapping • Spatial interpolation

  17. Study area – driving

  18. Digital photos

  19. Methods Digital photos • Driving the Puget Sound area • Digital photography

  20. Methods Digital photos • Driving the Puget Sound area • Digital photography

  21. Methods • Driving the Puget Sound area • Digital photography

  22. Methods • Driving the Puget Sound area • Digital photography • Image analysis • Quantification of color • GIS analysis of quantitative data • Mapping • Spatial interpolation Hue

  23. Methods • Driving the Puget Sound area • Digital photography • Image analysis • Quantification of color • GIS analysis of quantitative data • Mapping • Spatial interpolation

  24. Results • The data

  25. Results • The data • How to interpret it?

  26. Results: mapping

  27. Results: mapping

  28. Results: mapping

  29. Results: mapping

  30. Leaf color and elevation

  31. Leaf color and elevation Freezing level ?

  32. Spatial interpolation

  33. Spatial interpolation Spatial interpolation

  34. Data limitations • Image analysis problems • Differences in lighting • Selecting a tree to sample in each picture • Tree species loosely controlled • Limited sample size • Snapshot in time and on Earth • Therefore, claims may not be widely applicable

  35. Final Claim • Generally, leaf color hue decreases along the visible spectrum as elevation increases • Shown by data • Temperature drops as altitude increases • Known principle, observable in Cascades • Therefore, lower temperature = more intense leaf color

  36. Initial revised model Correlation Causal Elevation Spatial variability Adiabatic cooling Leaf color Temp. ? When leaves fall off Precip. Light Adiabatic cooling

  37. Final model Correlation Causal Elevation Adiabatic cooling More easily tested Leaf color Temp. When leaves fall off ? Precip. Hard to test locally Light Other factors Latitude

  38. Conclusions • Data shows: Lower temperature = more intense leaf color • We know that: Altitudinal succession = latitudinal succession • Remains unclear whether these two principles can be applied together on a larger scale • Regional/local limitation • Further research: road trip to Alaska • Control for tree species!

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