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Money!

Money!. If you want to do research with me and you have a GPA above 3.3 I can apply for a REU award from the National Science Foundation. Very prestigious award, worth about $5000. . Disturbance and succession. Sources of natural disturbance. Continental drift…… millions of years

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Money!

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  1. Money! • If you want to do research with me and you have a GPA above 3.3 • I can apply for a REU award from the National Science Foundation. Very prestigious award, worth about $5000.

  2. Disturbance and succession

  3. Sources of natural disturbance • Continental drift…… millions of years • Climate change………hundreds to thousands yrs • Volcanic……………..decades to hundreds yrs • Disease epidemics…..decades • Fire………………… annual to centuries • Freezes…………….. annual to decadal • Storm………………. monthly to decadal

  4. Fire • Huge wildfires are very destructive • Crown fires • Soil organics burn • C ignites at 500 oC these temperatures can penetrate 1m into soil.

  5. Destructive fires • Fire present for hours. • Plant rootstocks killed • Severe erosion follows • Large area burned, reduces source for recolonization.

  6. Most fires are not so severe • Light-moderate fires • Surface fires • High surface temperature, but at 2cm depth <50 oC. Fire passes in 2-5 minutes. • Many taller plants survive though scorched. • Animals either flee or survive in burrows. • Fire uneven, often leaves unburned/lightly burned patches • Roots remain, soil held. Everglades fire burning above the water

  7. Physical effects of fire • Scorching of leaves reduces productivity • Reduction of live biomass • Reduction of surface organics • Ashing and oxidation of soil chemicals • More soluble…more likely to be leached (solution). • Loose ash easily washed away (suspension). • Volatilization …loss of chemicals in smoke…70% of nitrogen.

  8. Fire can shape flora and hence fauna • Fire sensitive species are killed outright by fire. • Introduction of fire can change dominant species. • If fire is occasional leads to secondary succession. • If fire is frequent get a pyrophillic community adapted to fire.

  9. Adaptations for fire tolerance • Corky bark that insulates from heat • Root resprouting

  10. Epicormic buds • Epicormic buds…..buds beneath the bark that sprout following fire. • Epicormic sprouting is a sign of general stress on a plant.

  11. Australian “grass trees” flower as a result of exposure to smoke • Synchronizes flowering, so that insects pollinate flowers. • Burned area offers suitable habitat for seed to become established. • Note grass trees themselves may or may not have burned (these ones did).

  12. Natural fire regimes altered by: • Roads acting as fire breaks. • Fire suppression • Prescriptive burns

  13. What is the relationship between the variables here?

  14. Do the same observations apply to this reef?

  15. Intermediate disturbance Hypothesis (Connell 1978) • At very low disturbance competitive exclusion limits diversity. • At very high disturbance harsh conditions limit diversity. • Highest diversity at moderate disturbance regimes

  16. Fire is also bad if too frequent • S. Africa: Land on right burned too often and rare Proteas (shrubs) are missing

  17. Hubbard Brook • Long term ecological research (LTER) site. • Experimental deforestation, succession suppression and burns of entire stream catchments. • Effects measured in stream water.

  18. Net primary productivity and succession • NPP = GPP-respiration • NPP maximal in immature stages of succession. • Mature phase has senescent trees

  19. Hubbard Brook fire results Nitrate • Nitrate is an important nutrient. • Nitrate and sulfate are strong acid anions, and their leaching acidifies the streams, but will leave the soil more basic. Sulfate NO3 and SO4 content of streamwater following fires in their catchment

  20. Nutrient load Fire increases nutrient leaching • Nutrient flow from a burned area is elevated for 2-6 yrs post fire. • Oxidation of chemicals increases solubility, decreases acidity (increase of 2 pH units) • Sulfate concentrations in ELA streams: mean monthly SO4 concentrations in the Northwest stream before and after the 1980 fire. 1-2 yr after 3-7 yr after Pre-fire

  21. Seasonal variability • Nitrate stored in biomass and released in the spring melt. • Loss of biomass post fire.

  22. Hubbard brook clearcut (no fire) • Slower release of nitrate than following fire. • Why? Can you explain these patterns? • Watershed 2 is clearcut • Watershed 6 is control

  23. Fire summary • Disturbance depends on intensity of fire. • Frequent low intensity fires will shape composition of community to include fire tolerant species. • All effects of fire on the watershed may not be immediately apparent.

  24. Not just chemistry also basic biological questions • Has the fire promoted reproduction? • Has the fire promoted growth? • Has the fire increased or decreased the presence of insects, reptiles or mammals? • Has the fire stressed the plants, or were they totally fire adapted? • Are the impacts on wetlands that burn as severe as on uplands (or more so?)?

  25. Soil temperature in a tropical forest • Note how large clearing radically increases soil temperature. • Dry conditions lead to oxidation of surface litter and release of chemicals. Leaching a threat.

  26. Primary Succession

  27. Colonization of new areas Accreting shoreline (e.g. spit, building beach, sandbar) New volcanos New coral atolls Artificial reef Colonization of new areas

  28. Colonization of a new area • Follows succession from pioneers to competitors…..but all have to disperse there. • Distance from source is important…can larvae survive long enough to be transported there? Can seeds be blown there? Can mammals swim there? Can birds fly there?

  29. Two ways to study succession • Follow one location from disturbance to maturity, ex. Krakatau, Mt St Helens. • Select similar habitats at diffent times since similar disturbance, ex. Glacier Bay, building riverbank

  30. Succession in the intertidal • Macroalgal succession over 30 months on experimental concrete blocks. Ulva Sea lettuce

  31. Primary succession in Glacier Bay, Alaska • Steadily retreating glacier since 1850s. • New land surface revealed…primary succession. • Oldest succession where ice first retreated. 1912 1850

  32. Glacier Bay Succession • Retreating glaciers expose new land surface of till. • Rate of retreat ca. 65 km in 200 years • Succession follows broadly predicatable path

  33. Nutrient changes at Glacier Bay • The initial soil is nutrient poor. • Alder is an N-fixer, spruce and hemlock are not. • “forest floor” reflects N in leaf and wood litter. • Why is there a peak in forest floor N at the transition to spruce-hemlock. • Why does soil N decline in the spruce-hemlock zone?

  34. Simulation showing nitrogen inputs during 2ndry succession Importance of alder (ALRU) as a nitrogen fixer and Ceanothus (CEVE), early in succession. Lichens, and wood decomposition important (lesser) sources late in succession.

  35. Nitrogen sources

  36. Biotic and abiotic influences • Nitrogen likely to be limiting nutrient early in succession….why?

  37. r-K strategies

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