330 likes | 665 Views
Net Primary Productivity of Different Systems. Ecosystem Type Net Primary Productivity (kilocalories/meter 2 /year) Tropical Rain Forest 9000 Estuary 9000 Swamps and Marshes 9000 Savanna 3000
E N D
Net Primary Productivity of Different Systems Ecosystem Type Net Primary Productivity (kilocalories/meter2/year) Tropical Rain Forest 9000 Estuary 9000 Swamps and Marshes 9000 Savanna 3000 Deciduous Temperate Forest 6000 Boreal Forest 3500 Temperate Grassland 2000 Polar Tundra 600 Desert 200 * Kilocalories are what we call “Calories” in everyday usage
Controls on Net Primary Productivity Nutrients
In addition to primary productivity being a major sink for atmospheric CO2, it is also the base of the food chain and allows humans and all Other creatures to live, and… It takes a lot of primary production to support higher trophic levels! Data from Whittaker, R.H. 1961. Experiments with radiophosphorus tracer in aquarium microcosms. Ecological Monographs 31:157-188
Every Kg of predator needs 111Kg Of prey living in the same area for the System to stay stable 1. Carbone, C. & Gittleman, J.L. A common rule for the scaling of carnivore density. Science, 295, 2273 - 2276, (2002). 2.Enquist, B.J. & Niklas, K.J. Global allocation rules for patterns of biomass partitioning in seed plants. Science, 295, 1517 - 1520, (2002).
OK, so we need to know what control productivity both for Global climate and for organisms that live here (including humans!) We saw that water and temperature are very important, and that there Is a huge response to small change in water. But what about the Nutrients we talked about on Tuesday? What affect do they have?
Limiting Factors for Biological Productivity - Plants never seem to be able to “fix”, or assimilate all the carbon available to them – something is limiting production - This is true both on land and in the ocean Examples: Light can limit productivity, So can water, and Certain nutrients too CO2 rarely limits productivity
Only about 44% of the total Electromagnetic energy reaching the earth is in the correct wavelengths for use by plants (called PAR) and only 0.5% – 3% of that is used!
Temperature is a strong Limiting factor. Although plants in colder areas are optimized for Colder conditions
Water also is a strong Limiting factor. Much steeper curve = A much stronger positive Reaction i.e. a little water goes a long way!
If plants have enough water, enough sunlight, and are bathed in CO2, why don’t they “fix” more carbon, or grow more efficiently, faster, larger?
Liebig's Law of the Minimum In 1840, J. Liebig suggested that organisms are generally limited by only one single physical factor that is in shortest supply relative to demand.
Phosphorus Is very often limiting in freshwater systems What is happening here? Why doesn’t the line keep Going up?
Liebig's Law of the Minimum In 1840, J. Liebig suggested that organisms are generally limited by only one single physical factor that is in shortest supply relative to demand. Now thought to be inadequate – too simple! - complex interactions between several physical factors are responsible for distribution patterns, but one can often order the priority of factors
Multiple or co-limiting factors – often it is more Complex than Liebig’s Law of the minimum Look what happens with the addition of N
Multiple or co-limiting factors – often it is more Complex than Liebig’s Law of the minimum
As we’ve seen in the ocean and on land, nutrients are often limiting. Why nutrients? Needed for enzymes, cellular structures, etc. Pretty much analogous to vitamins for humans Soon as you meet the requirements for one, another ends up being limiting
Nutrient elements needed for all lifeC HOPKINS Mg CaFe run by CuZn Mo Carbon Molybdinum Hydrogen Zinc Oxygen Copper Phosphorus Iron Potassium Iodine Calcium Nitrogen Sulfur Magnesium
Order of Importance of Nutrient Elements in Different Environments On LandIn FreshwaterIn the Ocean 1) Nitrogen 1) Phosphorus 1) Iron 2) Phosphorus 2) Nitrogen 2) Phosphorus 3) Potassium 3) Silica 3) Silica
Fertilization increased growth and respiration Eucalyptus Carbon Budget (Tons C ha-1 yr-1)
Eucalyptus in Hawaii January 1999, 55 months after planting
Nutrient Inputs to Ecosystems Important nutrients for life generally enter ecosystems by way of four processes: (1). Weathering (2).Atmospheric Input (3). Biological Nitrogen Fixation (4). Immigration Red means humans have a huge impact on these processes
Nutrient Outputs from Ecosystems Important nutrients required for life leave ecosystems by way of four processes: (1).Erosion (2). Leaching (3). Gaseous Losses (4). Emigration and Harvesting Red means humans have a huge impact on these processes
Nutrient flux in Ecosystems INPUTS Weathering Atmospheric Input Biological Nitrogen Fixation Immigration OUTPUTS Erosion Leaching Gaseous Losses Emigration/Harvesting
In well functioning ecosystems relatively small amounts of Nutrients enter or leave. Most of what is needed comes from internal recycling! (true for all systems not just aquatic)
Excess Nitrogen Deposition – Too much of a good thing! Because Nitrogen often limits plant growth humans have gone to great lengths to use it as fertilizer It is also a by product of all types of combustion The net result is that we have altered the natural way that Nitrogen cycles more than we have any other element -including Carbon
In an undisturbed nitrogen cycle the element cycles very Efficiently – it is valuable so not readily given up by biota
160 In an undisturbed nitrogen cycle the element cycles very Efficiently – it is valuable so not readily given up by biota But humans add HUGE amounts of Nitrogen to the ecosystem
Nitrogen containing Compounds N2 – nitrogen gas NO3 – nitrate NO2 - nitrite NH4 – ammonium NH3 – ammonia N2O – Nitrous Oxide Organic Nitrogen – Living and dead plants And animals