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Collaborators Augusto Franco M. Haridasan Erika Geiger Sybil Gotsch Lucas Silva Davi Rossatto

Tropical plant trait evolution and the consequences for savanna-forest transitions William A. Hoffmann North Carolina State University. Collaborators Augusto Franco M. Haridasan Erika Geiger Sybil Gotsch Lucas Silva Davi Rossatto. The Cerrado. What determines tree cover in savannas?.

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Collaborators Augusto Franco M. Haridasan Erika Geiger Sybil Gotsch Lucas Silva Davi Rossatto

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  1. Tropical plant trait evolution and the consequences for savanna-forest transitionsWilliam A. HoffmannNorth Carolina State University CollaboratorsAugusto FrancoM. HaridasanErika Geiger Sybil GotschLucas SilvaDaviRossatto

  2. The Cerrado

  3. What determines tree cover in savannas?

  4. What determines the distribution of forest and savanna?

  5. Sparse tree cover • Dense grass • Dense tree cover • no grass • Cool, moist microclimate • Infrequent, mild fire • Hot, dry, windy microclimate • Frequent fire

  6. Miconia pohliana (Savanna species) Miconia cuspidata (Forest species)

  7. Symplocos rhamnifolia (Savanna species) Symplocos mosenii (Forest species)

  8. Large areas of the tropics have climates in which either savanna or forest vegetation in possible Staver et al (2011)

  9. C4 grasses became abundant only in the past 8 million years Cerling et al 1997 Nature 389:153-158

  10. Simon et al 2009 Savanna trees and shrubs began to arise from forest ancestors approximately 10 million years ago.

  11. There have been at least 115 independent origins of savanna trees or shrubs Black = forest taxa Red = savanna taxa Hoffmann (unpublished)

  12. Main questions • What selective pressures have shaped the evolution of tree species in savanna? • What are the consequences of savanna tree adaptations for ecosystem properties and vegetation dynamics?

  13. The multiple, independent origins of savanna lineages is ideal for comparative studies Black = forest taxa Red = savanna taxa

  14. Savanna and forest species differ substantially in traits that have large implications for ecosystem structure and dynamics Note that this is a comparison of forest and savanna species.

  15. 53% of the evolutionary transitions from forest to savanna were associated with a shift to a smaller growth form.

  16. Question 2: What are the consequences of these adaptations for ecosystem properties and vegetation dynamics?

  17. Savanna and forest species survive fire equally well

  18. The fire trap (Bell 1984) Long time without fire Fire

  19. The fire trap (Bell 1984) Long time without fire Short time without fire Fire

  20. The fire trap (Bell 1984) Long time without fire Short time without fire Fire Fire

  21. The fire trap (Bell 1984) Long time without fire Short time without fire Fire

  22. The fire trap (Bell 1984) Long time without fire Short time without fire Fire Fire

  23. An analogous threshold exists for ecosystems

  24. An analogous threshold exists for ecosystems Short time without fire

  25. An analogous threshold exists for ecosystems Short time without fire Fire

  26. An analogous threshold exists for ecosystems Long time without fire Short time without fire Fire

  27. An analogous threshold exists for ecosystems Long time without fire Short time without fire Fire Fire

  28. Resource manipulation experiment 10m x 70m plots CONTROL NUTRIENTS WATER WATER + NUTRIENTS

  29. Tree growth is more strongly limited by nutrients than by water

  30. High-resource sites permit more rapid canopy closure High resource site Low resource site

  31. At what point is each thresholds reached? • How big must a tree be to avoid topkill? • How dense must the canopy be to substantially reduce flammability?

  32. Hoffmann et al (2012) Ecology Letters

  33. Hoffmann et al (2012) Ecology Letters

  34. A growing stem becomes fire resistant when its bark thickness exceeds 6 mm 5.9 mm Hoffmann et al (2012) Ecology Letters

  35. A growing stem becomes fire resistant when its bark thickness exceeds 6 mm 9.1 mm 5.9 mm Hoffmann et al (2012) Ecology Letters

  36. 30 10 -30 -10 Distance (m) • Microclimate • Wind speed • Relative humidity • Temperature BehavePlus 5 (fire behavior model) • Fuels • Mass • Moisture • Bulk density Hoffmann et al (2012) Austral Ecology

  37. Fire simulations with BehavePlus

  38. Flammability of savanna is determined primarily by the presence of grass

  39. The canopy density at which grasses are excluded is a critical transition between savanna and forest.

  40. Thus we have two critical thresholds • A tree reaches a fire-resistance threshold when it accumulates a bark thickness of about 6 mm. • The ecosystem reaches a fire-suppression threshold when it attains a leaf area index of about 3.

  41. As savanna trees grow, they accumulate bark thickness more quickly than forest species

  42. As savanna trees grow, they accumulate bark thickness more quickly than forest species Threshold bark thickness

  43. As savanna trees grow, they accumulate bark thickness more quickly than forest species Threshold bark thickness 4.7 cm 10.2 cm

  44. Recall that forest species grow more quickly than savanna species when growing in the same environment

  45. Expected total time under stochastic fire regime

  46. Under a typical fire regime a forest tree has little chance of reaching maturity in savanna But, there is safety in numbers

  47. Sparse tree cover • Dense grass • Dense tree cover • no grass • Cool, moist microclimate • Infrequent, mild fire • Hot, dry microclimate • Frequent fire

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