1. Ecology
The first law of ecology is that everything is related to everything else.
~Barry Commoner

2. Warm-Up Do this on your OUTPUT side!
Think of your favorite outdoor spot.
List all of the living things that exist there.
List all of the non-living aspects of your experience there.

3. The Biosphere
Chapter 34

4. Concept 34.1 The biosphere is the global ecosystem. Key Terms Ecology
Biotic factor
Abiotic factor
Population
Community
Ecosystem
Biosphere
Habitat

5. The Study of Ecology Ecology Biotic vs. Abiotic
Study of interactions among organisms and their environments
Biotic vs. Abiotic

6. Ecological Relationships
Classified by broad levels:
Organisms
Populations
Communities
Ecosytems
Biosphere

7. Individual Organisms Smallest unit of ecological study
Ecologists ask questions about the adaptations that enable individuals to meet the challenge of their environment

8. Populations
Group of the individual organisms of the same species living in a particular area
Ecologists often ask questions about factors that affect the size and growth of a population

9. Communities All of the organisms inhabiting a particular area
Ecologists investigate interactions among all of the organisms in a community

10. Ecosystems Includes the biotic and abiotic factors in an area
Questions at the ecosystem level may relate to the flow of energy and chemicals

11. Biosphere Broadest of all levels of ecological study
Sum of all of the Earth’s ecosystems
Questions at the biosphere level involve global issues, such as investigating the effects of climate change on living things

12. Patchiness of the Biosphere
Differences in the abiotic factors of a location leads to a “patchy” appearance like a quilt
Each of these “patches” are different habitats for organisms to live in

13. Chlorophyll Concentrations

14. Key Abiotic Factors Sunlight
Provides light and warmth and is an energy source for all ecosystems
Water
Essential to all life on Earth – all organisms contain water
Temperature
Life exists at a very narrow range of temperatures (0-50°C)
Soil
Product of abiotic forces and the actions of living things
Wind
Can affect the distribution and activities of organisms
Severe Disturbances
Naturally affect the ecosystems – fire, hurricanes, droughts,

16. Concept 34.2 Climate determines global patterns in the biosphere.
Key Terms
Tropics
Polar zones
Temperate zones
Current
Microclimate

17. Uneven Heating of the Earth’s Surface
The angle that the sun’s rays hit the Earth causes different temperature gradients
Tropics
Polar Zones
Temperate Zones

18. Wind, Precipitation & Ocean Currents
Global wind patterns and Earth’s rotation create warm and cold surface currents in the oceans
These surface currents affect the climate on the continents

20. Local Climate Local climate can be affected by: Bodies of Water
Mountains

21. Microclimate
Climate in a specific area that varies from the surrounding climate region
Microclimates can be created by:
Shade
Snow cover
Windbreaks

22. Concept 34.3 Biomes are the major types of terrestrial ecosystems.
Key Terms
Biome
Tropical rain forest
Savanna
Desert
Chapparral
Temperate grassland
Temperate deciduous forest
Coniferous forest
Tundra
Permafrost

23. What is a Biome?
Major types of terrestrial ecosystems that cover large areas of Earth
Biomes are characterized by communities of plants and other organisms that are adapted to its climate and other abiotic factors

24. Tropical Rainforest Characterized by tall trees Contain epiphytes
Treetops = Canopy
Contain epiphytes
Don’t get enough sunlight at the floor of the rainforest
Often live on the branches of tall trees
Not parasitic because they make their own food

25. Tropical Rainforest Highest species richness Animals:
1 Hectare = 300 species
Temperate forest
1 Hectare = 10 species
Animals:
Sloth, colorful birds, monkeys, snakes, and lizards
Maybe be 8 million species of beetles in the rain forest

26. Savanna
Tropical or subtropical grasslands with scattered trees and shrubs
Alternating wet and dry seasons
More rain than deserts
Less rain than rainforests

27. Savanna Animals: Zebras, giraffes, and gazelles
Lions, leopards, and cheetahs

28. Desert Receive less than 25 cm of rainfall per year
Deserts are NOT hot all the time
Desert vegetation is often sparse and consists of plants that have adapted to the dry climate

29. Desert Plant adaptations:
Waxy coating
Protective spines
Plants and animals have adaptations to conserve what little water they receive
Animals:
Kit foxes, snakes, and lizards

30. Chaparral Dominated by dense evergreen shrubs
Dry climate consists of mild, rainy winters and hot, dry summers

31. Chaparral
Chaparral’s dry, woody shrubs often ignite by lightning and are adapted to survive periodic brushfires

32. Temperate Grassland
Form in the interior of continents, at about the same latitude of temperate deciduous forests
Known by different names in different places:
Prairie = N. America
Steppes = Asia
Pampas = S. America
Veldt = Africa

33. Temperate Grassland
Because of its rich soil – grasslands have been transformed into farmland for crops such as wheat and corn
Very little undisturbed portions of the grasslands in the world

34. Temperate Deciduous Forest
Characterized by trees who lose their leaves in the fall
These regions have pronounced seasons, with precipitation throughout the year

35. Temperate Deciduous Forest
Animals:
Deer, foxes, squirrels, and raccoons
Large areas of temperate deciduous forests have been cut down for timber or cleared to make room for farms, towns, and cities

36. Coniferous Forest / Taiga
South of the tundra
Dominated by cone-bearing trees (pines, firs, hemlocks, and spruce)
Plants in the taiga are adapted to long and cold winters, short summers, and nutrient-poor soils

37. Coniferous Forest / Taiga
Typical animals:
Moose
Bears
Wolves
Lynx
Some animals stay in the forest year-long
Many species hibernate 6-8 months of the year

38. Tundra
Cold and largely treeless, surface covered with permafrost (permanently frozen soil)
Receives little precipitation

39. Tundra Tundra plants are usually small and grow slowly Animals
Grasses, sedges, and mosses
Animals
Caribou, musk oxen, snowy owls, artic foxes, lemmings, and snowshoe hairs

41. Concept 34.4 Aquatic ecosystems make up most of the biosphere.
Key Terms
Photic zone
Phytoplankton
Aphotic zone
Benthic zone
Estuary
Pelagic zone
Intertidal zone
Neritic zone
Oceanic zone
Zooplankton
Hydrothermal vent

42. Aquatic Ecosystems
Water covers ¾ of the Earth and is home to a variety of organisms
Freshwater zones
Lakes and ponds
Rivers and streams
Estuaries
Ocean zones
Intertidal zone
Neritic zone
Oceanic zone

43. Freshwater Zones Low levels of salt (0.0005% salinity)
Freshwater ecosystems include:
Lakes
Ponds
Streams
Rivers

44. Lakes and Ponds Freshwater Lakes and Ponds support: Eutrophic
Otters, Muskrats, Birds (Ducks and Loons), and Fish
Eutrophic
Rich in organic matter and vegetation
Water is relatively murky
Oligotrophic
Very little organic matter
Water is much clearer, bottom is usually sandy or rocky

45. Lakes and Ponds

46. Rivers and Streams
Body of water that flows down a gradient towards its mouth
Water flows swiftly down steep gradients, organisms are adapted to withstand powerful currents
Brook trout face upstream to catch passing drifting invertebrates
Slow-moving rivers and backwaters are richer in nutrients and support more life
Rooted plants and fishes are adapted to weaker currents in slow-moving rivers

47. Rivers and Streams

48. Estuaries Place where freshwater meets sea water Examples:
Bays
Mud flats
Salt marshes
Inhabitants are adapted for frequent changes
Mangrove trees have salt glands that secrete salt from salt water

49. Estuaries

50. Ocean Zones
The ocean covers 70% of the Earth’s surface, with an average depth of 3.7 km
At the deepest parts the depth is 11km deep
Different Oceanic Zones
Aphotic – cold and dark, no sunlight
Photic – receives sunlight
Intertidal – along the oceanic shore, tides rise and fall
Neritic – relatively shallow, just beyond the intertidal zone
Pelagic – open ocean
Benthic – ocean bottom

51. Ocean Zones

52. Oceanic Zones

53. Intertidal Zone
Organisms in this zone are adapted to periodic exposure to air during low tide
Crabs avoid dehydration by burrowing into the sand or mud
Organisms in this zone must be able to withstand the force of crashing waves
Sea anemones cling to rocks
Sea stars use tube feet to adhere to surface

54. Intertidal Zone

55. Neritic Zone Most productive zone of the ocean
Waters are rich in plankton
Coral reefs are productive and rich in species
Animals:
Many species of fish
Crustaceans
Mollusks

56. Neritic Zone

57. Oceanic Zone Fewer species than neritic zone
Half of the photosynthesis that occurs on Earth takes place in oceanic zone
Producers of the upper parts are protists and bacteria in the plankton

58. Oceanic Zone
In the aphotic zone, animals feed mostly on sinking plankton and dead organisms
Deep-sea organisms must cope with the near freezing temperature and crushing pressure
Deep sea vents lead to adaptations from organisms -> Deep sea tube worms

59. Oceanic Zone

60. Population and Community Ecology
Chapter 35

61. How many species are there?
WARM - UP
How many species are there?

62. Concept 35.1
A population is a local group of organisms of ONE species.
Key Terms
Population density

63. What is a Population?
Alligators living in a swamp make up a population—members of the same species living in a specific geographic area.
Other populations in the swamp include diverse species of trees, egrets and other birds, and the various species of fishes, algae, and microorganisms in the swamp water.

64. Defining Populations
Several factors influence a population's size and how much it changes over time. They include the availability of food and space, weather conditions, and breeding patterns.
In studying how these factors affect a population, ecologists need to define the population's geographic boundaries.
Natural
Artificial

65. Population Density
Population density is the number of individuals of a particular species per unit area or volume.
The number of alligators per square kilometer of swamp, the number of bacteria per square centimeter of an agar plate, and the number of earthworms per cubic meter of soil are all examples of population density measurements.
Population density   =  Individuals  =  1000 trees  =  20 trees  
Unit area  km2  km2

66. Sampling Techniques
It usually isn't practical to count every member of a population. There may be too many individuals, or they may move around too quickly to be counted accurately, as with many species of insects, birds, and fish.
In such cases, ecologists use a variety of sampling techniques to estimate the size of the population.
Quadrats
Indirect Counting
Mark-Recapture
Limits to Accuracy

67. Sampling Techniques Quadrats
One method is to mark off a particular area, then count the number of a particular species within this boundary
After repeating this procedure in several locations within the ecosystem, ecologists average their results to estimate the population density of this species in the ecosystem

68. Sampling Techniques Indirect Counts
A sampling technique for organisms that move around a lot or are difficult to see is indirect counting
This method involves counting nests, burrows, or tracks rather than the organisms themselves

69. Sampling Techniques Mark-Recapture
The biologist traps animals in the study area and marks them, such as with a drop of colored dye.
The researcher then releases the marked individuals.
After a period of time, the researcher again captures animals from the population and counts the marked and unmarked individuals in the second sample.
Total population  =   # in 1st capture * # in 2nd capture  
# of marked animals recaptured

70. Mark-Recapture

71. Limits to Accuracy
Most sampling techniques involve making some assumptions about the population being studied. If these assumptions are not valid, then the estimate will not be accurate.
For example, the quadrat method assumes that organisms are distributed fairly evenly throughout the study area.
The mark-recapture technique assumes that both marked and unmarked animals have the same chance of surviving and of being caught in the second capture.

72. Warm-Up
Charles Darwin calculated that a single pair of elephants could increase to a population of 19 million individuals within 750 years.
Why isn’t the world overrun with elephants?
What type of factors may have influenced the population growth of the elephants?

73. Concept 35.2 There are limits to population growth. Key Terms
Exponential growth
Limiting factor
Carrying capacity
Density-dependent factor
Density-independent factor

74. Population Dispersion
Spatial distribution of organisms (spacing)
Clumped
Even
Random

75. Clumped Distribution Individuals are clustered together
Occurs when resources such as food and living space are clumped together
Occurs also with social behavior
Fish in schools
Birds in flocks

76. Even Distribution
Results from social interactions where individuals are trying to get as far away from each other as possible
Gannets staking claim on a specific area of the coast from its neighbors

77. Random Distribution Results from seed dispersal by the wind or birds
Forests
Wildflowers

78. Population Dynamics
All populations are dynamic – they change in size and composition over time
In order to understand these changes – you need to look at:
Birth rate
Death (Mortality) rate
Life Expectancy

79. Birth vs. Death (Mortality) Rates
Number of births occurring in a period of time
In the United States there are 4 million births per year
Number of deaths occurring in a period of time
In the United States there are 2.4 million deaths per year
The average length an individual is expected to live
In the United States in 1996, the life expectancy for a man was 72 years, and for a woman is was 79 years

80. Patterns of Mortality
The mortality rate of different species tend to conform to one of three curves on a graph
These curves are called “survivorship curves” because they show the likelihood of survival at different ages throughout the lifetime of an organism

81. Survivorship Curves Red = Type I Green = Type II Blue = Type III
Likelihood of dying is small until later in life
Humans & elephants
Green = Type II
Probability of dying does not change, is constant
Bird species
Blue = Type III
Many organisms die young, the few who survive live long lives
Oysters, salmon, and insects

82. Population Growth Rate
Demographers = scientists who study population dynamics
Growth rate of a population = the amount by which a population’s size changes in a given time
Whether a population grows, shrinks, or remains the same size depends on four processes.
Birth, Death, Immigration, and Emigration

83. Population Growth Processes
Birth and Immigration add to a population
Death and Emigration subtract individuals from a population
Birth rate – Death rate = Growth rate

84. Exponential Growth (J-shaped)
Population increases rapidly after only a few generations; the larger a population gets, the faster it grows
We can predict that the population will grow indefinitely and at an increasingly rapid rate based on this model
Limitations = populations can only grow indefinitely with unlimited resources

85. Logistic Model (S-shaped)
Builds on the Exponential Model by accounting for the influence of limiting factors
Employs K (carrying capacity)
The number of individuals the environment can support over a long period of time

86. Limiting Factors Factors that restrain the growth of a population
Resources depleted or shrinking
Waste build-up
Competition among individuals

87. 2 Types of Limiting Factors
Density-independent
Reduces the population by the same proportion, regardless of the population’s size
Examples: weather, flood, fires
Density-dependent
Resource limitations (such as food shortages or nesting sites) are triggered by increasing population density

88. Population Fluctuations
Population fluctuations are linked to environmental changes.
Lynx and Snowshoe hares

89. Perils of Small Populations
Rapidly growing human population has caused extreme reductions in the populations of some other species and subspecies
Siberian tigers – less than 200 left in the wild due to over hunting and habitat destruction
California condors – by the 1980’s, the condor’s wild population was down to 9 individuals

90. More Perils of Small Populations
Small populations are more vulnerable to extinction due to:
Environmental disturbances (storms, fires, floods, or diseases)
Inbreeding – lack of genetic variability
More susceptible to diseases and have a shorter life span
Example: Cheetahs

91. Concept 35.3
Biologists are trying to predict the impact of human growth on the world.
Key Terms
Age Structure

92. Age Structure
The distribution of individuals among different ages in a population
Populations with a high percentage of young individuals have a greater potential for rapid growth

93. Population Age Structures

94. History of Human Population Growth
Until 10,000-12,000 years ago the human population grew very slowly
Hunter-gatherer lifestyle
Low population growth rate due to small populations and high mortality rates
Infants and young children rarely reached reproductive maturity

95. Development of Agriculture
Humans learned how to domesticate animals and cultivate plants for food
Change from hunter-gatherer to agriculturists
Called the Agricultural Revolution
Increase in available food supply
Human population grew faster

96. Population Explosion
Human population growth accelerated after 1650 because of a sharp decline in death rates
Reason for decline:
Better sanitation
Increased availability of food
Improved economic conditions

97. Human Population Growth
It took most of human history for the population to reach 1 billion (1800), however it only took 27 years ( ) for the population to grow from 3 billion to 5 billion

98. Population Growth Today
Even though birth rates have decreased, the population is still increasing
20% of the population live in developed countries
U.S., Japan, Germany, France, United Kingdom, Australia, Canada, and Russia
Better educated, healthier, and live longer
80% of the population live in developing countries
Central America, South America, Africa
Poorer, populations grow much faster

99. The Future of the Human Population
Human population growth will eventually stop, however we do not know when
How large will the population be?
Will the planet be able to support the population over a long period of time?
The answer to these questions will depend on whether we use our resources wisely

100. Human Populations Lab

101. Demographics Lab
You can look at cemeteries in order to document trends in human populations

102. In this lab you will calculate the age of individuals located in 4 different plots in a cemetery
After calculating the ages, you will document the data on a data table and graph your results

103. Concept 35.4 Species interact in biological communities. Key Terms
Interspecific competition
Competitive exclusion
Niche
Predation
Symbiotic relationship
Parasitism
Mutualism
Commensalism

104. Symbioses 5 Major Types of Close Interactions Predation Parasitism
Competition
Mutualism
Commensalism

105. Predation
Predators capture, kill, and consume another individual, the prey
Natural Selection favors adaptations that improve the efficiency of predators in finding, capturing, and consuming their prey
Natural Selection favors adaptations that allow prey to avoid, escape, or ward off predators

106. Predators & Prey Example:
Rattlesnakes have adaptations for locating their prey (frogs, etc) with an acute sense of smell and with specialized heat sensitive pits located below each nostril

107. Mimicry Deception is important in anti-predator defenses
Two types of Mimicry
A harmless species resembles a poisonous or distasteful species
Two or more dangerous species look similar so that when a predator encounters one it will avoid similar individuals

108. Mimicry in action…
Can you see the mantis in the pictures?

109. Mimicry in action…
The scarlet king snake (top) mimics the pattern of the eastern coral snake (bottom) so that predators will avoid it
Scarlet King Snake = non-poisonous
Eastern Coral Snake = poisonous

110. Toxic Prey
This poison arrow frog escapes predation because its bright colors signify a toxic taste

111. Plant vs. Herbivore Interactions
Some plants develop adaptations to avoid animals that eat plants (herbivores)
Physical defenses – sharp thorns, spines, sticky hairs, and tough leaves
Chemical defenses – secondary compounds that are poisonous, irritating, or bad-tasting
Strychnine and nicotine (toxic to insects)
Poison ivy and oak produce a skin-irritating substance
Drugs like morphine, atropine, codeine, taxol, and quinine are derived from secondary compounds

112. Parasitism
Species interaction that resembles predation, where one individual is harmed and the other benefits; however, the parasite feeds on the other individual (the host)
While most forms of predation removes an organism from the population, parasitism does not result in the immediate death of the host
Often the parasite feeds off of the host for a long time instead of killing it

113. Ectoparasites
External parasites – live ON their host and do not enter the host’s body
Examples:
Ticks
Fleas
Lice
Lampreys
Leeches
Mosquitoes

114. Endoparasites Internal parasites – live INSIDE the host’s body
Examples:
Disease-causing bacteria
Protists (like malaria parasites)
Tapeworms

115. Parasite Adaptations Parasites have specialized anatomy and physiology
Example: The tapeworm doesn’t even have a digestive system – instead they absorb nutrients through their skin
Host Adaptations:
Skin is an important defense against parasites
Openings (eyes, mouth, and nose) are defended chemically by tears, saliva, and mucus

116. Competition
Results from a niche overlap – where resources are used by two or more species
Interspecific Competition – species compete for the same resources
Savanna Grasslands
First studies on competition were performed by G.F. Gause on two species of paramecia

118. Competitive Exclusion
Joseph Connell’s study on barnacles (Balanus and Chthamalus)
Two species of barnacles competing for space on the rocks
Balanus crowded out the Chthamalus in the lower tidal zone

120. Competitive Exclusion
The composition of a community may change through competitive exclusion
Competitors may adapt niche differences or anatomical differences that lessen the intensity of competition
These differences are often greatest where the ranges of potential competitors overlap
Called character displacement

121. Adaptive Radiation Darwin’s Finches
Example of character displacement because their beak differences allow for them to feed on different foods and in turn reduce competition
Resource Partitioning

122. Mutualism
Cooperative relationship in which both species derive some benefit from the relationship
Some mutualistic relationships are so close that neither species can survive without the other
Pollination is a mutualistic relationship
Animals feed on the flower
Animal is covered with pollen and carries it to other flowers and pollinates them

123. Mutualism Lichens Coral polyps contain dinoflagellates
Made up of a fungi and an algae
Coral polyps contain dinoflagellates

124. Commensalism
Commensalism is an interaction in which one species benefits and the other is not affected
Example:
Clown Fish and Sea Anemone

125. Concept 35.5 Disturbances are common in communities. Key Terms:
Ecological succession
Primary succession
Secondary succession
Introduced species

126. Species Richness vs. Diversity
The number of species a community contains
Counts the species in a community
Species Diversity
The number of species in a community and the relative abundance of the species in the community
Suggests the species’ importance because it takes into account how common the species is in the community

127. Patterns of Species Richness
Varies with Latitude
The closer to the Equator = more species
Hypotheses:
Temperate habitats are younger, due to the ice age
Climate is more stable in the tropics
Plants can photosynthesize all year long in the tropics, allowing more food to support more organisms

129. Species/Area Effect
Larger areas contain more species than smaller areas
Larger areas usually contain a greater diversity of habitats and can support more species

130. Reducing the size
of the habitat
reduces the number
of species is can support

131. Species Interaction and Species Richness
Interactions among species (Symbioses) promote species richness
Predators can prevent competitive exclusion
Example:
Pisaster

132. Pisaster vs. Mytilus

133. Community Stability
Community Stability = A community’s resistance to change
Species richness improves community stability
Grass plots with more species took less time to recover from drought
Grass plots with more species lost a smaller percentage of land mass than plots with less species

134. Succession
Disturbances such as fires, landslides, hurricanes, and floods trigger a sequence of changes in communities
The gradual, sequential re-growth of species in an area is called succession

135. Disturbances to Communities
Large scale
Small scale

136. Primary Succession
Development of a community in an area that has NOT supported life previously, such as bare rock, sand dunes, or an island formed by volcanic eruptions
Proceeds very slowly because minerals necessary for plant growth is unavailable
Lichens
Plants
Trees
Pine, Balsam, and Spruce Forests

138. Secondary Succession
Sequential replacement of species that follow disruption of an existing community
May stem from a natural disaster (forest fire or a strong storm)
Could happen following human activities (farming, logging, and mining)
Commonly takes about 100 years for the original ecosystem to return through a series of well-defined stages
Annual grasses (dandelions, grasses)
Perennial grasses and shrubs
Trees
Deciduous forest

140. Pioneer Species vs. Climax Community
The species that predominates early in succession
Tends to be small, fast-growing, and fast-reproducing
Climax Community => Stable End Point
The organisms in each stage alter the physical environment in ways that make it less favorable for their own survival, but more favorable for the organisms that succeed them

141. Human Activities & Species Diversity
Clearing the Land
Forests cleared for farmland or housing
Introduced Species
Kudzu – introduced to help stop erosion
Grew out of control and took over the landscape

142. Ecosystems and Conservation Biology
Chapter 36

143. Concept 36.1
Feeding relationships determine the path of energy and chemicals in the ecosystems.
Key Terms
Producer
Consumer
Decomposer
Trophic level
Food chain
Herbivore
Carnivore
Omnivore
Primary consumer
Secondary consumer
Tertiary consumer
Detritus
Food web

144. Energy Flow & Chemical Cycling

145. Concept 36.2 Energy flows through ecosystems. Key Terms Biomass
Primary productivity
Energy pyramid
Biomass pyramid
Pyramid of numbers

146. Energy Flow
Energy is passed from one organism to another in the ecosystem
In order to follow the energy flow we group organisms based on how they obtain energy
Trophic Levels

147. Trophic Level
The organism’s position in the sequence of energy transfer
Most ecosystems contain only 3-4 trophic levels

148. Energy Transfer Food Chain Food Web
Single pathway of feeding relationships
Ex. Grass seeds -> Mouse -> Snake -> Hawk
Food Web
Linking of 2 or more food chains

149. Food Chains

150. Food Webs

151. Energy Pyramid

152. Biomass Pyramids

153. Output Assignment Design 3 Food Chains
Must have at least 3 individual organisms
Incorporate those 3 Food Chains into a Food Web
Create a meal for a human that incorporates 2 different Trophic levels

154. Concept 36.3 Chemicals cycle in ecosystems. Key Terms
Nitrogen Fixation
Nitrification
Transpiration

155. KWLH Chart – Output WarmUp
Before Taking Notes:
Write down 3 things you KNOW about any of the biogeochemical cycles
Write down 3 things you WANT to find out about the biogeochemical cycles

156. Ecosystem Cycles Each substance travels through a biogeochemical cycle
Energy flows through the ecosystem and is recycled and reused
Each substance travels through a biogeochemical cycle
Water Cycle
Carbon Cycle
Oxygen Cycle
Nitrogen Cycle

157. Basic Pattern of Chemical Cycling
Producers incorporate chemicals from the non-living environment into organic compounds
Consumers feed on the producers, incorporating some of those chemicals into their own bodies and releasing some back into the environment as waste products
As organisms die, decomposers break them down, further supplying the soil, water, and air with chemicals in inorganic form

158. Water Cycle Cells contain 70-90% water
Found in a number of places in the environment
Cells
Ground water
Water vapor in the atmosphere

159. Evaporation Transpiration Precipitation
Adds water to the atmosphere as water vapor
Heat causes water to evaporate from bodies of water, the soil, and living things
Transpiration
Plants take in water through their roots and it is released from their leaves into the atmosphere
Animals drink water and then release it when they breathe, sweat or excrete
Precipitation
Water is leaving the atmosphere via rain, snow, sleet, hail or fog

161. Carbon-Dioxide & Oxygen Cycles
Two processes...
Photosynthesis
Plants and other autotrophs use carbon dioxide with water and sunlight to make carbohydrates
Cellular Respiration
Autotrophs and Heterotrophs use oxygen to break down carbohydrates into water and carbon dioxide

164. Human Influence on the Carbon Cycle
Burning fossil fuels adds carbon dioxide into the atmosphere +
Destruction of vegetation (clear-cutting) =
Less carbon cycling

165. Nitrogen Cycle
All organisms need nitrogen to make proteins and nucleic acids
Plants absorb nitrates from the soil
Animals obtain nitrogen by eating plants and digesting the proteins and nucleic acids
78% of the atmosphere = Nitrogen

166. Nitrogen Cycle… Nitrogen Fixation Converts nitrogen gas to nitrate
Nitrogen-fixing bacteria convert N2 gas into ammonia, then nitrite, then nitrate, which plants can use
Ammonification
Decomposers break down the corpses and wastes of organisms and release the nitrogen that they contain as ammonia

167. Nitrogen Cycle… Nitrification Denitrification
Bacteria in the soil take up ammonia and oxidize it into nitrites and nitrates
Denitrification
Anaerobic bacteria break down nitrates and release nitrogen gas back into the atmosphere

169. KWLH Chart – Output WarmUp
After Taking Notes:
Write down 3 things you LEARNED about the biogeochemical cycles
Write down 3 ideas of HOW we can learn more about the biogeochemical cycles

170. Concept 36.4 Human activities can alter ecosystems. Key Terms
Deforestation
Greenhouse effect
Global warming
Eutrophication
Acid rain
Pollution
Biological magnification
Ozone

171. Impact on Chemical Cycles
Human activities can affect chemical cycles by moving the nutrients from place to place
Deer – eats plants in a forest and returns the waste to the same location
Humans – eat a salad and then their waste may be carried out to the ocean

172. Carbon Cycle Impacts
Burning of wood and fossil fuels increase carbon dioxide in the atmosphere
Deforestation – eliminated plants that use carbon dioxide for photosynthesis
Greenhouse effect – process in which atmospheric gases trap heat
Global warming – overall rise in Earth’s temperature

173. Greenhouse Effect

175. Nitrogen Cycle Impacts
Human activities move large portions of nitrogen into the water or air
Eutrophication
Fertilizer runs off into a water source causing algae blooms
Acid Rain
Nitrogen and Sulfur combine to create acid rain in the atmosphere

176. Eutrophication

177. Acid Rain

178. Water Cycle Impact
Deforestation – Removes trees that return water to the atmosphere through transpiration, reduces the amount of water vapor and changes precipitation patterns

179. Other Effects of Pollution
Pollution – addition of substances to the environment that results in negative effects
Biological Magnification
Damage to the Ozone Shield

180. Biological Magnification
Gradual accumulation of chemicals inside of an organism because it cannot excrete the pollutants
DDT
Used to combat mosquitoes
Accumulates in fat cells (lipids) and is magnified through the food chain

181. PCB’s & DDT

182. Damage to the Ozone
Some pollution affects a gas called ozone (O3) to break down
A major contributor to the destruction of the ozone are chloroflurocarbons (CFCs) released from aerosol cans, refrigeration units, and manufacturing processes

183. Ozone Hole & CFC’s

184. DDT Debate Are the benefits of DDT worth the costs?
Roles of the debater:
Environmentalist - environmental stance on DDT use
Govt. Official in charge of Environmental Policy
World Health Organization investigating Malaria and other mosquito-based disease Prevention

185. Warm-Up
Brainstorm 3-5 past/present products that are derived from threatened species.
Ex. Taxol, a cancer drug, derived from yew trees threatened by deforestation
Ex. Ivory for piano keys or jewelry, comes from elephants threatened by overhunting
Step beyond blaming humans for evil/greed:
Why can protecting threatened species be a tough issue to solve?

186. Concept 36.5 Conservation biology can slow the loss of biodiversity.
Key Terms
Biodiversity
Overexploitation
Conservation biology
Zoned reserve
Buffer zone
Sustainable development

187. Conservation & Biodiversity
Conservation = protecting and sustaining resources for the future
Biodiversity =
Variety of life on Earth
Variety of ecosystems in the biosphere
Genetic variety among individuals in a species
Why does it matter?
Because EVERYTHING is connected!
If one species was to disappear – it would affect the entire ecosystem!

188. Biodiversity: Importance to Humans
Source of beauty/inspiration
Oxygen, food, clothing, and shelter
Aids in the development of medicines
25% of medicine in the U.S. contain substances from plants
Possibility of discovering new products for human use
Rosy periwinkle – yields a medicine used to treat 2 forms of cancer (childhood leukemia & Hodgkin’s disease)
Deforestation in Madagascar threatens this species

189. Mass Extinctions
There are periods in Earth’s history where mass extinctions caused a number of species to become extinct
Signs of another mass extinction taking place:
~11% of the 9,040 known bird species in the world are endangered
Of the ~20,000 known plant species in the U.S., at least 680 species are endangered
~20% of the world’s freshwater fish have either become extinct or are endangered

190. Threats to Biodiversity
Conservation Biologists use the acronym HIPPO to summarize global threats to biodiversity
H = Habitat Destruction
I = Introduced Species
P = Pollution
P = Population Growth
O = Overexploitation

191. Habitat Destruction
As the human population grows – more land is needed for agriculture, roads, and communities
If an organism that required that habitat does not adapt or move - it will not survive
Some changed to a habitat causes it to be fragmented (building a road through a forest) preventing species from using resources in all parts of the forest

192. Introduced Species
Introduced (non-native) species often prey on native species or compete with them for resources
Starlings and House Sparrows competing with native Bluebirds

193. Overexploitation
The practice of harvesting or hunting to such a degree that the small number of remaining individuals may not be able to sustain the population
Examples:
Over-fishing
Poaching

194. Conservation Biology Approaches
Goals of Conservation Biology
Finding solutions
Carrying out the solutions
Possible Approaches
Focusing on hot spots
Understanding an organism’s habitat
Balancing demands for resources
Planning for a sustainable future

195. Hot Spots
Earth’s biodiversity “hot spots” are home to an enormous variety (2/3 of ALL plant and vertebrate) of species, many of which are endangered.
Biodiversity hot spots also tend to be “hot spots” for extinction – this makes them a top priority with conservation biologists, lawmakers, and local communities working together to preserve those locations.

197. Understanding Habitats
Understanding the habitat requirements of a species can help biologists manage its existing habitat or create new habitat areas
Red-Cockaded Woodpecker

198. Balancing Demands for Resources
In many cases a tug-of-war exists between efforts to save species and the economic and social needs of people
Should a wooded habitat be conserved in an effort to save an owl population if it means putting hundreds of loggers out of work?
Remember the DDT debate?
Politicians, townspeople, and conservation biologist can reach resolutions by reviewing scientific data, weighing costs and benefits, looking for alternative solutions, and casting their votes.

199. Planning for a Sustainable Future
Costa Rica has established 8 zoned reserves in an effort to conserve biodiversity while meeting the needs of humans
People live and work in the buffer zones surrounding the park reserves

200. Planning for a Sustainable Future
Many nations, scientific organizations, and private foundations are working toward a goal of sustainable development – developing natural resources so that they can renew themselves and be available for the future.
The challenge for individuals and nations is to find a way to meet the needs of Earth’s human population, while conserving ecosystems and resources for the planet’s other populations as well.

201. Output – Conclusion
What types of things could you do in your life that will impact the environment in a positive way?