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Ecosystem Ecology

Ecosystem Ecology. Ecosystem Ecology I. Introduction - Ecosystem: an assemblage of organisms, together with their chemical and physical environments. Ecosystem Ecology I. Introduction - “Box Models” of Exchanges (“fluxes”) between “reservoirs”. Ecosystem Ecology I. Introduction

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Ecosystem Ecology

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  1. Ecosystem Ecology

  2. Ecosystem Ecology • I. Introduction • - Ecosystem: an assemblage of organisms, together with their chemical and physical environments

  3. Ecosystem Ecology I. Introduction - “Box Models” of Exchanges (“fluxes”) between “reservoirs”

  4. Ecosystem Ecology I. Introduction - “Box Models” of Exchanges (“fluxes”) between “reservoirs” - matter (of a type: C, H2O, N, P) or energy

  5. Ecosystem Ecology I. Introduction II. Energy Flow

  6. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 1. Gross Primary Productivity Total photosynthetic productivity: CO2 + H20 -----> Glucose + O2

  7. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 1. Gross Primary Productivity Total photosynthetic productivity: CO2 + H20 -----> Glucose + O2 Metabolism Growth Reproduction

  8. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 1. Gross Primary Productivity Total photosynthetic productivity: CO2 + H20 -----> Glucose + O2

  9. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass RESPIRATION ------ Metabolism Growth GPP NPP Reproduction

  10. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements

  11. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP

  12. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light

  13. In aquatic systems, water filters light energy…so there is a given “depth” at a given time of day, for a given type of organism, at which R = GPP; NPP = 0)

  14. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light - water

  15. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light - water - temp

  16. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light - water - temp - nutrients

  17. 2. Net Primary Productivity: - factors affecting NPP - Nutrients: Nutrient Use Efficiency = grams of dry mass produced/gram of nutrient absorbed Lower NUE for a nutrient means it is more limiting (need more to produce the same biomass).

  18. 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light - water - temp - nutrients - Global Patterns

  19. 2. Net Primary Productivity: - energy stored in biomass - measurements - factors affecting NPP - light - water - temp - nutrients - Global Patterns

  20. Annual Cycle in Global Productivity

  21. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 3. Net Secondary Productivity - assimilations efficiencies – A/I seed eaters: 60-80% browsers: 30-40% detritivores: 15%

  22. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 3. Net Secondary Productivity - assimilations efficiencies – A/I seed eaters: 60-80% browsers: 30-40% detritivores: 15% herbivores: 60-70% carnivores: 80-90%

  23. Low AE? Must eat more to get energy needed. Horse – ‘hindgut ruminant’ – less efficient, high throughput Cattle – ‘foregut ruminant’ – more efficient, can eat less.

  24. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity N:P :: 50:1 3. Net Secondary Productivity - affected by nutrient ratios, growth rates, and most limiting variable. May need to eat a lot to get enough of the limiting variable. N:P :: 15:1 Fast growing; need higher ratio of Phosphorus for DNA synthesis.

  25. Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 3. Net Secondary Productivity - Net Production Efficiency = P/A

  26. NSP What might this depend on??? NPP

  27. 0.5% Birds Ecosystem Ecology I. Introduction II. Energy Flow A. Productivity 0.7% Shrews 3. Net Secondary Productivity - net production efficiency = P/A 6-10% Most Mammals Up to 75% for sedentary poikilotherms

  28. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids

  29. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • - ecological efficiency: NSP/NPP (5-20%) NPP of Secondary Carnivores Loss due to 2nd Law NPP of Primary Carnivores NPP of HERBIVORES NPP of Producers (PLANTS)

  30. a. trophic "pyramids" This is why large carnivores are RARE, and why they have large RANGES NPP of Secondary Carnivores Loss due to 2nd Law NPP of Primary Carnivores NPP of HERBIVORES NPP of Producers (PLANTS)

  31. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • DetritalFoodchains Predators Herbivores

  32. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • DetritalFoodchains NPP Detritivores Herbivores Temperate forest: 1.5% - 2.5% Old-field Habitat: 12% Plankton: 60-99%

  33. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • DetritalFoodchains • ‘Biomass Accumulation Ratios’ If we know the mean ‘standing crop’ of biomass from year to year, and we know the net productivity, we can calculate how long, on average the biomass persists: BAR (per year) = (biomass/m2) / (np of biomass / m2 / yr)

  34. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • DetritalFoodchains • ‘Biomass Accumulation Ratios’ If we know the mean ‘standing crop’ of biomass from year to year, and we know the net productivity, we can calculate how long, on average the biomass persists: BAR (per year) = (biomass/m2) / (np of biomass / m2 / yr) Forests: ~ 20 years Tropical leaf litter: 3 months Phytoplantkon: ~20 days Temperate leaf litter: 2-20 years

  35. Ecosystem Ecology • I. Introduction • II. Energy Flow • Productivity • Trophic Pyramids • DetritalFoodchains • BAR • Human Concerns

  36. E. Human Concerns

  37. E. Human Concerns: NPP

  38. E. Human Concerns: NPP

  39. E. Human Concerns 500% increase in 50 years, with population increase of 250%

  40. E. Human Concerns A doubling of meat production per capita

  41. E. Human Concerns 25% of catch by weight discarded

  42. E. Human Concerns

  43. E. Human Concerns 6-10 lbs of feed for 1 lb increase in cattle weight 2-5 lbs of fish meal for 1 lb increase in farmed fish weight

  44. Edible kilocalories produced from kilocalories of energy required for cultivation are: 18.1% for chicken, 6.7% for grass-fed beef, 5.7% for farmed salmon 0.9% for shrimp. 123% for potatoes 250% for corn 415% for soy input calories converted to calories able to be utilized by humans E. Human Concerns So, for every 100 calories of energy we put in to raise chickens, we get 18 calories of energy produced in chicken meat. 100 cal into soy, 415 calories out.

  45. E. Human Concerns Food production, per capita (400 kg per year is healthy minimum)

  46. SO HOW DID WE DO IT?

  47. E. Human Concerns EXTENSIFICATION – MORE AREA

  48. E. Human Concerns EXTENSIFICATION – MORE AREA

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