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Ecosystems . What they are?. Plum Island. 1) What are Ecosystems?. Ecosystems are the biotic and abiotic factors in a specified area that interact with one another.
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Ecosystems What they are?
1) What are Ecosystems? Ecosystems are the biotic and abiotic factors in a specified area that interact with one another. • Understanding the interaction of the biotic and abiotic factors in an ecosystem can help us to see why particular human activities may be a problem for human survival. • Example: The loss of ozone in the stratosphere increases the quantity of UV radiation on the surface of the planet. In the same way that humans experience sunburn from too much sun exposure, so do plants. Excessive UV may damage or destroy plant protein and DNA, killing the plant.
Important ecological terms • Ecology: Study of ecosystems and the interactions that occur among organisms and between organisms and their environment • Ecologist: The investigators who conduct ecological studies
Important ecological terms • Species: All the members of a specific kind of plant, animal or microbe; a kind given by similarity of appearance or capacity for interbreeding and producing fertile offspring • Biotic communities: All the populations of different plants, animals and microbes occupying a given area. • Abioticfactors: All the factors of the physical environment: moisture, temperature, light, wind, pH, type of soil, salinity, etc.
Important ecological terms • Populations: All the members of a particular species occupying a given area. • Associations: A plant community with a definite composition, uniform habitat characteristics, and uniform plant growth.
Important ecological terms • Ecotone: transitional region that shares many of the species and characteristics of two ecosystems. It also includes unique conditions • Fig.An ecotone may create a unique habitat with specialized species not found in either of the ecosystems bordering it.
Important ecological terms • Landscapes: group of interacting ecosystems in a particular area. A barrier island, a saltwater bay, constitute a landscape Fig. Ecosystems are not isolated from one another. One ecosystem blends into the next through a transitional region, an ecotone, which contains many species common to the two adjacent systems.
Important ecological terms • Biomes: grouping of all the ecosystems of a similar type. I.e. tropical rain forests, grasslands, deserts, etc. • Biosphere: All the species on Earth, along with all the environments, make up one vast ecosystem, the Biosphere.
2) The structure of Ecosystems Feeding relationships Trophic structure
Trophic structure Producers Primary consumers Secondary consumers
Trophicstructure • Producers: capture energy from the Sun or chemical reactions to convert carbon dioxide, an inorganic molecule into organic matter. • What is the difference between organic and inorganic molecules? • Producers are also known as autotrophs. What is an autotroph?
Trophic structure 2) Consumers: • Primary consumers: feed directly on producers (herbivores) • Secondary consumers: feed on primary consumers (carnivores) • Omnivores: feed on both plants and animals Consumers are also known as heterotrophs. What is an heterotroph?
The Structure of Ecosystems Feeding relationships among consumers Predator/prey relationships: any relationship in which one organism feeds on another. Parasites: plants or animals that become intimately associated with their “prey” and feed on in over an extended period of time without killing it. The organism that is fed upon is called host. Pathogens: bacteria and viruses that cause disease
Trophic structure 3) Detritus feeders and decomposers: Organisms that feed on death plants or animals, feaces, etc. • Primary detritus feeders: organisms that feed directly on detritus • Decomposers: secrete digestive enzymes that break down dead matter. I.e. bacteria and fungi. • Secondary detritus feeders: feed on primary detritus feeders. I.e. protozoans, mites, insects, and worms. • Are detritus feeders autotrophs or heterotrophs?
2) The structure of Ecosystems Feeding relationships Trophic relationships
Trophic relationships a. Food chains: feeding pathways • Food chains are a description of who eats whom. • Predator-prey and host-parasite describe specific feeding relationships. b. Food webs: complexes of feeding relationships. c. Trophic Levels or Feeding Levels • All producers belong to the first trophiclevel. • All herbivores (primary consumers) are on the second trophiclevel. • All primary carnivores (secondary consumers) are on the third trophic level.
TrophicRelationships Food chain Food web
2) The structure of Ecosystems Feeding relationships Biomass and biomass pyramids
Biomass and biomass pyramid • All organic matter can be defined as biomass • All biomass can be arranged into a feeding relationship with the producers on the first trophic level. • On average, 10% of the energy from one trophic level moves to the next trophiclevel. (This is due partly to the First and Second Laws of thermodynamics.) At each trophiclevel most of the organisms are not consumed, portions of organisms consumed pass through the consumer undigested, and energy is released to the environment as high potential energy is converted to low potential energy.
Biomass and biomass pyramid • Because so little energy can be transferred between trophic levels, it is necessary that the first trophic level contain the greatest number of organisms, and the subsequent trophic levels contain fewer and fewer organisms. Limitations on the transfer of energy between trophic levels creates the biomass pyramid. • If organisms (humans) eat high on the biomass pyramid (trophic levels 3, 4, 5, etc.), then fewer organisms can be supported than if organisms eat lower on the biomass pyramid.
2) The structure of Ecosystems Non-feeding relationships
Non feeding relationships • Mutually Supportive Relationships: mutualism. • Competitive Relationships • How are competitive relationships reduced?HabitatNiche: resource partitioning • What happens when competition is not reduced?Competitive exclusion principle
ABIOTIC FACTORS • Conditions: abiotic factors that vary in space and time, but are not used up or made unavailable to other species. i. e. temperature, wind, pH, salinity, fire • Resources: factors (biotic or abiotic) that are consumed by organisms. i.e. water, chemical nutrients, light, oxygen
2) The Structure of Ecosystems Limiting Factors • Factors that limit growth, reproduction or even survival of a population. • Biotic or abiotic • Basic items include temperature, light, oxygen, carbon dioxide, and precipitation. • Only one limiting factor need be out of its optimum range to cause stress for an organism.
Optimum, zones of stress and limits of tolerance • Optimum: level at which an organisms do best. • Range of tolerance: the entire span that allows any growth at all. • Limits of tolerance: points at the high and low ends of the range of tolerance • Zones of stress: between the optimal range and the high or low limit of tolerance Range of tolerance
Limiting factors • Law of Limiting Factors - Quantities of any single factor above or below optimum levels necessary for organism growth, reproduction, or survival will limit growth, reproduction, or survival. • Synergistic effects (synergism): two or more factors interacting in a way that causes an effect much greater than one would anticipate from the effects of each of the two acting separately.
3) Global biomes The Role of Climate
The role of climate • Climate: describes the average temperature and precipitation of a given region • Weather the daily variations in temperature and precipitation • Vary widely in different parts of the world. • A given climate supports only those species that find the temperature and precipitation levels optimal or within ranges of tolerance. • Temperature and precipitation combine to create the world's biomes.
Activity: Describe how ecosystems change as temperature and precipitation change: a. Vary temperature while precipitation is held constant (Moderate rainfall: cold = cooltundra, warmer = grassland) b. Vary precipitation while temperature is held constant (Cold temperature: little rain = tundra, more rain = cool taiga).
3) Global biomes Microclimate
Microclimate MicroclimateSpecificsites with temperature and moisture conditions significantly different from the overall or average climate of the region in which it is located. Microclimates. Abiotic factors such as terrain, wind, and type of soil create different microclimates by influencing temperature and moisture in localized areas
4) Implications for humans The three revolutions: • Neolithic Revolutiona. Development of agricultureb. Required permanent or long term settlements and specialized skillsc. Allowed for the initial increase in human population reliable food. • Industrial Revolutiona. Created the modern worldb. Energized by fossil fuels (initially timber). resulted in the concentration of waste productsd. Created even greater increase in human population size because of the specialization of the workforce and the replacement of animal/human power with fossil fuels. • Environmental Revolutiona. Need to create sustainable human systemsb. Need to create systems in which waste products are not concentrated (pollution), and wastes are resources.
http://www.harmonartillustrations.com/store/murals.php • http://emilyyyyyyyyyy.glogster.com/food-web-/ • http://drake.marin.k12.ca.us/stuwork/rockwater/PLANKTON/Food%20Chain.htm • http://cumuseum.colorado.edu/Research/Objects/sep04_lichens.html • http://www.colorado.edu/geography/courses/geog_1001_lab/ • http://apesnature.homestead.com/chapter2.html • http://www.exploringnature.org/db/detail.php?dbID=45&detID=2589 • http://gohealed.com/ • http://pediaview.com/openpedia/Detritivore