1. Honors Biology CH. 24 p. 634-647 CH. 25 p. 652-659, 663-668, 673-677 Ecology

2. Ecology Ecology is the study of organisms within their environment. Ecology is the study of organisms within their environment. Matter cycles Matter cycles Energy flows Energy flows The sun is the ultimate source of energy on earth The sun is the ultimate source of energy on earth Trophic level- one step in a food chain or pyramid Trophic level- one step in a food chain or pyramid

3. Ecology terms Habitat- the place where a population of a species lives Habitat- the place where a population of a species lives Community- the different species that live within the habitat Community- the different species that live within the habitat Ecosystem- the biotic and abiotic factors of a habitat Ecosystem- the biotic and abiotic factors of a habitat Abiotic- the physical aspects of a habitat (soil, air, water) Abiotic- the physical aspects of a habitat (soil, air, water) Biotic- the living things in a habitat Biotic- the living things in a habitat

4. Food Chains Producers- photosynthetic organisms that capture energy from the sun. Producers- photosynthetic organisms that capture energy from the sun. Consumers- organisms that consume plants or other organisms to obtain energy. Consumers- organisms that consume plants or other organisms to obtain energy. Decomposer- Bacteria and fungi that eat decayed organisms. Decomposer- Bacteria and fungi that eat decayed organisms.

5. Food Chains Herbivores- animals that eat plants and other producers Herbivores- animals that eat plants and other producers Carnivores- animals that eat other animals Carnivores- animals that eat other animals Omnivores- animals that eat both plants and animals Omnivores- animals that eat both plants and animals Detritivores- organisms that eat organic wastes from dead organisms Detritivores- organisms that eat organic wastes from dead organisms

6. Energy Pyramid

7. 10% Rule Only 10% of the energy from one trophic level moves up to the next. Only 10% of the energy from one trophic level moves up to the next. 90% of the energy is lost -- given off as heat or wasted energy. 90% of the energy is lost -- given off as heat or wasted energy.

8. Biogeochemical cycles The Water cycle The Water cycle Evaporation- water heated to water vapor Evaporation- water heated to water vapor Condensation- water vapor becomes clouds Condensation- water vapor becomes clouds Precipitation- Rain, Hail, Snow, Sleet etc. Precipitation- Rain, Hail, Snow, Sleet etc. Runoff- drains into streams, rivers, lakes, oceans Runoff- drains into streams, rivers, lakes, oceans Percolation- water goes into soil with ground water Percolation- water goes into soil with ground water Transpiration- water released from plants Transpiration- water released from plants

9. The Water Cycle

10. Carbon Cycle Photosynthesis- plants fix CO 2 in the air to make organic materials. Photosynthesis- plants fix CO 2 in the air to make organic materials. Respiration- plants and animals through cellular respiration release CO 2 into the air. Respiration- plants and animals through cellular respiration release CO 2 into the air. Combustion- when plants, wood, and fossil fuels (organic materials turned into coal, oil, and gas) are burned CO 2 is released into the atmosphere. Combustion- when plants, wood, and fossil fuels (organic materials turned into coal, oil, and gas) are burned CO 2 is released into the atmosphere. Erosion- exposed limestone will release CO 2 into the water or air. Erosion- exposed limestone will release CO 2 into the water or air.

11. Greenhouse Effect Greenhouse gases- H 2 O, CH 4, CO 2, NO, O 3, and CFC’s absorb solar energy that is reflected by the earth the atmosphere Greenhouse gases- H 2 O, CH 4, CO 2, NO, O 3, and CFC’s absorb solar energy that is reflected by the earth the atmosphere The Greenhouse Effect keeps the earth’s surface temperature stable. The Greenhouse Effect keeps the earth’s surface temperature stable. But the concentration of CO 2 increases due to combustion causing rises in the temperature of the earth. But the concentration of CO 2 increases due to combustion causing rises in the temperature of the earth.

13. The Nitrogen Cycle N 2 gas in the atmosphere is fixed in the soil by lightning and nitrogen fixing bacteria. N 2 gas in the atmosphere is fixed in the soil by lightning and nitrogen fixing bacteria. Plant roots take in nitrogen in the form of ammonia (NH 3 ) nitrates (NO 3 -1 ) to make proteins. Plant roots take in nitrogen in the form of ammonia (NH 3 ) nitrates (NO 3 -1 ) to make proteins. Animals obtain nitrogen from there food. Animals obtain nitrogen from there food. Decomposition of dead organisms and wastes returns nitrogen to the soil Decomposition of dead organisms and wastes returns nitrogen to the soil Denitrifying bacteria returns nitrogen in the soil back into N 2 gas in the atmosphere. Denitrifying bacteria returns nitrogen in the soil back into N 2 gas in the atmosphere.

14. The Nitrogen Cycle ~78% of the atmosphere is unusable N 2. ~78% of the atmosphere is unusable N 2. Living things need nitrogen to build amino acids and nucleic acids Living things need nitrogen to build amino acids and nucleic acids Nitrogen fixation- N 2 gas is fixed in the soil by lightning and nitrogen fixing bacteria. Nitrogen fixation- N 2 gas is fixed in the soil by lightning and nitrogen fixing bacteria. Ammonification- bacteria in the soil convert decomposing organic materials into NH 3. Ammonification- bacteria in the soil convert decomposing organic materials into NH 3. Nitrification- ammonia is converted to to nitrites and nitrates Nitrification- ammonia is converted to to nitrites and nitrates Assimilation- Plant roots take in nitrogen in the form of ammonia (NH 3 ) nitrates (NO 3 -1 ) to make proteins Assimilation- Plant roots take in nitrogen in the form of ammonia (NH 3 ) nitrates (NO 3 -1 ) to make proteins Denitrification- reduction of nitrates by bacteria into nitrogen gas. Denitrification- reduction of nitrates by bacteria into nitrogen gas.

16. Limiting Factors Limiting Factors- an environmental factor such as food, temperature, water, or sunlight that restricts growth, metabolism or population size. Limiting Factors- an environmental factor such as food, temperature, water, or sunlight that restricts growth, metabolism or population size. Productivity of ecosystems and their organisms is affected by limiting factors. Productivity of ecosystems and their organisms is affected by limiting factors. A resource in short supply keeps growth in check. A resource in short supply keeps growth in check. Competition for an abundant resource can keep individual populations in check. Competition for an abundant resource can keep individual populations in check. Population Density- the number of individuals in an area. Population Density- the number of individuals in an area.

17. Density Independent Factors Limiting Factor that is not affected by size of the population Limiting Factor that is not affected by size of the population Most important: Most important: Weather Weather Climate Climate

18. Density Dependent Factors Limiting Factor that is more effective as population density increases Limiting Factor that is more effective as population density increases Especially affects long lived organisms Especially affects long lived organisms Competition for food and other resources Competition for food and other resources Predation Predation Parasitism Parasitism

19. Exponential Growth If there is little competition for a resource, the population may experience a period of exponential growth. If there is little competition for a resource, the population may experience a period of exponential growth.

21. Logistic Growth As population density (and competition) increases, growth becomes logistic and levels of at the carrying capacity. As population density (and competition) increases, growth becomes logistic and levels of at the carrying capacity. Carrying Capacity (k)- the maximum population size that can be supported by the available resources in a given area. Carrying Capacity (k)- the maximum population size that can be supported by the available resources in a given area.

23. Exponential (J-Curve) vs. Logistic Growth (S-Curve)

24. Boom and Bust Cycle If growth is exponential until the carrying capacity is reached (and overshot), a massive death rate will follow. If growth is exponential until the carrying capacity is reached (and overshot), a massive death rate will follow.

25. Predator-Prey Cycle If the limiting factor is inconsistent, population size emulates the fluctuations with a bit of a lag If the limiting factor is inconsistent, population size emulates the fluctuations with a bit of a lag

27. Predator Prey Cycle

28. Human Population Growth Why doesn’t environmental resistance take effect? Why doesn’t environmental resistance take effect? Altering the environment Altering the environment Technological advances in Technological advances in Culture Culture Agriculture Agriculture Industry Industry Medicine Medicine

30. Ozone Layer Earth’s atmosphere is divided into several layers, the lowest layer is called the troposphere, and next layer is called the stratosphere Earth’s atmosphere is divided into several layers, the lowest layer is called the troposphere, and next layer is called the stratosphere The Ozone Layer is not an actual layer but a concentration of O 3 molecules, located in the stratosphere, which is about 15-30km above Earth The Ozone Layer is not an actual layer but a concentration of O 3 molecules, located in the stratosphere, which is about 15-30km above Earth The ozone layer absorbs a portion of the radiation from the sun, preventing it from reaching the planet’s surface. The ozone layer absorbs a portion of the radiation from the sun, preventing it from reaching the planet’s surface. Most importantly it absorbs the portion of ultraviolet light called UVB Most importantly it absorbs the portion of ultraviolet light called UVB

31. Ozone Depletion In the early 1970’s, researchers began to investigate the effects of CFC’s (chlorofluorocarbons) on the ozone In the early 1970’s, researchers began to investigate the effects of CFC’s (chlorofluorocarbons) on the ozone CFC’s contain chlorine, and are found in aerosol propellants, refrigerants, solvents, and many other products CFC’s contain chlorine, and are found in aerosol propellants, refrigerants, solvents, and many other products CFC’s are so stable only exposure to strong UV radiation breaks them down; once CFC’s are broken down chlorine is released CFC’s are so stable only exposure to strong UV radiation breaks them down; once CFC’s are broken down chlorine is released One chlorine atom can destroy over 100,000 ozone molecules One chlorine atom can destroy over 100,000 ozone molecules There is no actual “hole”, but a low concentration of O 3 There is no actual “hole”, but a low concentration of O 3

32. Ozone Depletion

34. Ultra Violent B UVB has been linked to skin cancer, cataracts, crop damage, and harm some forms of marine life UVB has been linked to skin cancer, cataracts, crop damage, and harm some forms of marine life

35. Montreal Protocol International Treaty to phase out and ban the use of CFC’s International Treaty to phase out and ban the use of CFC’s Opened for signatures in 1989, by 2009 all 196 countries of the United Nations had signed. Opened for signatures in 1989, by 2009 all 196 countries of the United Nations had signed.

36. Symbiosis Symbiosis- relationship of species that live together in a close, long term association. Symbiosis- relationship of species that live together in a close, long term association. Secondary compounds- defensive chemicals in plants or animals Secondary compounds- defensive chemicals in plants or animals Niche- the role a species plays within an ecosystem Niche- the role a species plays within an ecosystem Fundamental niche Fundamental niche Realized niche Realized niche Biodiversity- the variety of organisms and species within an ecosystem. Biodiversity- the variety of organisms and species within an ecosystem.

37. Symbiotic Relationships Competition (-,- ) species using the same resources. Competition (-,- ) species using the same resources. Predation (+,-) one organism kills another for food. Predation (+,-) one organism kills another for food. Parasitism (-,+) a parasite benefits and a host is harmed. Parasitism (-,+) a parasite benefits and a host is harmed. Mutualism(+,+) symbiosis where both species benefit. Mutualism(+,+) symbiosis where both species benefit. Commensalism(+, 0) - relationship where one species benefits and the other is neither harmed or helped. Commensalism(+, 0) - relationship where one species benefits and the other is neither harmed or helped. http://www.nearctica.com/ecology/pops/symbiote.htm http://www.nearctica.com/ecology/pops/symbiote.htm http://www.nearctica.com/ecology/pops/symbiote.htm

38. Biomes Biome- a large area with a type of climate and certain types of plants and animals. Biome- a large area with a type of climate and certain types of plants and animals. Climate- the physical conditions and average weather conditions of a particular area over a long period of time. Climate- the physical conditions and average weather conditions of a particular area over a long period of time. Moisture Moisture Temperature Temperature

39. Terrestrial Biomes Tropical Rain Forest Tropical Rain Forest Savannas Savannas Taiga Taiga Deserts Deserts Temperate Grassland Temperate Grassland Temperate Deciduous Forest Temperate Deciduous Forest Temperate Evergreen (Coniferous) Forest Temperate Evergreen (Coniferous) Forest Tundra Tundra http://www.mbgnet.net/index.html http://www.mbgnet.net/index.html http://www.mbgnet.net/index.html

40. Convection Cells

41. Location of the Worlds Biomes Tropical Rainforest will be located around the Equator due to hot, humid air from Hadley Cell. Tropical Rainforest will be located around the Equator due to hot, humid air from Hadley Cell. Deserts will be located around 30° N and 30° S due to cool dry air from the Hadley Cell and Ferrel Cell Deserts will be located around 30° N and 30° S due to cool dry air from the Hadley Cell and Ferrel Cell Taiga will be located around 60° N due to wet air from the Ferrel and Polar Cell Taiga will be located around 60° N due to wet air from the Ferrel and Polar Cell

42. Mountain Effect On the windward side of a mountain, warm wet air from prevailing winds will rise, cool and condense causing precipitation. On the windward side of a mountain, warm wet air from prevailing winds will rise, cool and condense causing precipitation. On the leeward side of a mountain, air that travels over the mountain will be cool and very dry. On the leeward side of a mountain, air that travels over the mountain will be cool and very dry. Dry biomes like deserts and grasslands can be created on the leeward side of the mountain. Dry biomes like deserts and grasslands can be created on the leeward side of the mountain.

43. Mountain Effect

44. Succession Ecosystems change over time as species are introduced by natural means or abiotic factors. Ecosystems change over time as species are introduced by natural means or abiotic factors. Pioneer species are organism that are first to live in an area. Pioneer species are organism that are first to live in an area. Climax Community- a stable, self perpetuating plant and animal community established by succession. Climax Community- a stable, self perpetuating plant and animal community established by succession.

45. Primary Succession Ecosystems change over time as species are introduced by natural means or abiotic factors. Ecosystems change over time as species are introduced by natural means or abiotic factors. Primary Succession occurs in an area with newly exposed rock, lava, or sand, where life has not lived before. Primary Succession occurs in an area with newly exposed rock, lava, or sand, where life has not lived before. retreated glacier retreated glacier lava cooling lava cooling new beach forms new beach forms Etc. Etc.

46. Primary Succession Primary Succession begins with bare rock, and pioneer species like lichen, mosses, and or small annual grasses- which enriches the soil. Primary Succession begins with bare rock, and pioneer species like lichen, mosses, and or small annual grasses- which enriches the soil.

47. Secondary Succession Secondary Succession- the sequential replacement of species after a major disruption in a community where there has been life before. Secondary Succession- the sequential replacement of species after a major disruption in a community where there has been life before. forest fire forest fire flood flood climate change climate change cultivation cultivation plowed field plowed field clearcut forest, etc. clearcut forest, etc.

48. Secondary Succession If fertile soil is present secondary succession replace established species as new species become more competitive. If fertile soil is present secondary succession replace established species as new species become more competitive.

49. Invasive Species Natural Selection favors organisms that can disperse and then colonize new territory. Natural Selection favors organisms that can disperse and then colonize new territory. Plants use wind and animals for dispersal, animals can move great distances. Plants use wind and animals for dispersal, animals can move great distances. Barriers like continents, mountains, and inhospitable conditions provide barriers for exotic species. Barriers like continents, mountains, and inhospitable conditions provide barriers for exotic species. Exotic (Invasive) Species that overcome natural barriers can damage ecosystems. Exotic (Invasive) Species that overcome natural barriers can damage ecosystems. The ecosystem has no checks on the exotic species- which upset balance. The ecosystem has no checks on the exotic species- which upset balance.