UNIT 4 ECOLOGICAL STUDIES I INTRODUCTION TO ECOLOGY

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UNIT 4 – ECOLOGICAL STUDIES I. INTRODUCTION TO ECOLOGY (pp. 63, 64, 98 -104)

UNIT 4 – ECOLOGICAL STUDIES I. INTRODUCTION TO ECOLOGY (pp. 63, 64, 98 -104)

Founder of Ecology n Ernst Haeckel – “Oikos”

Founder of Ecology n Ernst Haeckel – “Oikos”

A. Introduction n Ecology is the study of interactions between organisms and their environment;

A. Introduction n Ecology is the study of interactions between organisms and their environment; therefore the study of ecology includes biotic, or _living_ factors, as well as abiotic (non-living_) factors.

B. Levels of Organization 1. _Species______ - a group of similar organisms that can

B. Levels of Organization 1. _Species______ - a group of similar organisms that can interbreed and produce fertile offspring

B. Levels of Organization n n 2. _Population__ - a group of organisms that

B. Levels of Organization n n 2. _Population__ - a group of organisms that belong to the same species and live in one area. The area in which an organism lives is known as its _habitat_. 3. __Community_ - many different species of organisms living in the same _habitat_ 4. _Ecosystem_ - a community and the _abiotic_ factors that affect it 5. _Biome____ - a group of ecosystems that have the same climate and similar _communities_ 6. _Biosphere_ - Earth

n n II. “THE STUDY OF. . . “ Ecologists spend large amounts of

n n II. “THE STUDY OF. . . “ Ecologists spend large amounts of time investigating interactions between _biotic_ and _abiotic_factors. It is important that ecologists have an understanding of experimental design. An experimental design that is flawed does not produce valid results or justifiable _conclusions.

A. Laboratory Investigations - There a variety of ways to conduct a laboratory investigation

A. Laboratory Investigations - There a variety of ways to conduct a laboratory investigation depending on the desired outcome. n n n 1. Comparative – A _comparison_____ of two or more things; for example, comparing plant cells with animal cells under the microscope 2. Descriptive – Observational lab in which quantitative (_involve numbers, measurements, quantities__) and qualititative (_descriptions__) information is obtained; for example, Seed Journal 3. Experimental – Designed experiment that follows the _scientific method____. Clearly defined _control___and test group(s).

n B. The Scientific Method (pp. 3 -15) The term, “scientific method” is misleading

n B. The Scientific Method (pp. 3 -15) The term, “scientific method” is misleading because it actually refers to a process that is neither reserved for ecologists and other scientists, nor a methodical set of steps to be followed in a specific order. Instead, it is an _organized__ pattern of thinking to solve everyday problems.

n n The Scientific Method - “How dull!”, you might say But it’s actually

n n The Scientific Method - “How dull!”, you might say But it’s actually a tool we use everyday To shop and compare and problemsolve, too It’s just a pattern of thinking in much that we do!

III. A CLOSER LOOK AT THE SCIENTIFIC METHOD n n n A. _Question or

III. A CLOSER LOOK AT THE SCIENTIFIC METHOD n n n A. _Question or Problem__ B. Forming a _hypothesis__ A hypothesis is a TESTABLE explanation or prediction

C. Setting Up a Controlled _Experiment_ n n To test a hypothesis or find

C. Setting Up a Controlled _Experiment_ n n To test a hypothesis or find an answer to a question, a scientist will usually set up a controlled experiment. A controlled experiment usually consists of two groups: 1. Control – Set-up used as a _benchmark or standard for comparison_

Experimental Group n 2. Experimental Group – Group in which all conditions are kept

Experimental Group n 2. Experimental Group – Group in which all conditions are kept the same except for a _single variable__. A variable is a _factor changed by the experimenter__. Only _one__ factor should be changed in each experimental group. This change is designed to _test the hypothesis. n a. Manipulated (independent) variable – factor that is _changed by the experimenter__ n b. Responding (dependent) variable – condition that is measured or observed as a result of the change

D. Collecting Data from an experiment should be presented in a concise and organized

D. Collecting Data from an experiment should be presented in a concise and organized manner. Often _graphs___ are used as a visual representation of the results. The types of graphs used most often to illustrate results are: 1. _Circle (Pie)_ Graph – Used to show relationship of a part to a whole n

Graphs n n 2. _Bar_ Graph – Used when independent variable isn’t continuous; for

Graphs n n 2. _Bar_ Graph – Used when independent variable isn’t continuous; for example, absorbency of different brands of paper towels 3. _Line__ Graph – Used when _independent____ variable is continuous; for example, time. A line graph most clearly shows the relationship between the independent & dependent variables in an experiment. In a line graph, the manipulated (independent) variable is plotted on the _X__ axis and the responding (dependent) variable is plotted on the _Y__ axis.

Where does distance go? Manipulated (Independent) Variable: _______MIX__________ Responding (Dependent) Variable: ____DRY_________

Where does distance go? Manipulated (Independent) Variable: _______MIX__________ Responding (Dependent) Variable: ____DRY_________

E. Analysis and Conclusion After collecting data, a scientist must analyze the data and

E. Analysis and Conclusion After collecting data, a scientist must analyze the data and form conclusions based on the following questions: 1. Do the results _support___ or _refute__ the _hypothesis_? n

Analysis and Conclusion n 2. Is the experimental set-up _valid___? a. Was there a

Analysis and Conclusion n 2. Is the experimental set-up _valid___? a. Was there a large enough _sample size___? b. Although no experimental set-up can be perfect, were the _sources of error_ minimized? c. Was there only _one variable___ tested? n 3. Is the experiment _repeatable__? n n n

F. Constructing a Theory n n A scientific theory is an explanation that has

F. Constructing a Theory n n A scientific theory is an explanation that has been _tested__ many times by many different _scientists_. Although a theory has been confirmed by repeated experiments, it may eventually be disproven.

IV. n n n ENERGY FLOW (pp. 67 -73) All living things require energy.

IV. n n n ENERGY FLOW (pp. 67 -73) All living things require energy. The ultimate source of energy for the earth is the _sun___. A. Autotrophs – “_Self-feeder____”. They are also known as _producers__. Most producers capture energy from the sun in a process called _photosynthesis_. Photosynthesis takes place in the_chloroplasts_ of plant cells. The equation for photosynthesis is_CO 2 + H 2 O + light energy → C 6 H 12 O 6 + O 2___.

Photosynthesis

Photosynthesis

B. Heterotrophs – Organisms that have to _obtain food_ are called heterotroph or _consumers____.

B. Heterotrophs – Organisms that have to _obtain food_ are called heterotroph or _consumers____. n n n There are several categories of consumers: 1. Herbivores – Eat _plants (producers)__ 2. Carnivores – Eat _animals (other consumers)__ 3. Omnivores – Eat _plants & animals_____ 4. Detritivores – Obtain energy from _dead bodies of plants and animals; for example, _worms, vultures, _ 5. Decomposers – Break down _organic__ matter. Most decomposers are in Kingdom _Eubacteria or Kingdom _Fungi_.

C. Energy in a Cell – All organisms (_producers_and _consumers_) must convert chemical__ energy

C. Energy in a Cell – All organisms (_producers_and _consumers_) must convert chemical__ energy present in _glucose_ and other food molecules into usable energy. This conversion process is known as _metabolism__ and the end-product is a re-chargeable “battery” used by all cells for energy known as _ATP___. Most ATP is produced through the process of _cellular respiration_. n The equation for cellular respiration is _ C 6 H 12 O 6 + O 2 → CO 2 + H 2 O +ATP__. n

IV. ENERGY FLOW – A COMPARISON OF PHOTOSYNTHESIS & CELLULAR RESPIRATION (p. 232) PHOTOSYNTHESIS

IV. ENERGY FLOW – A COMPARISON OF PHOTOSYNTHESIS & CELLULAR RESPIRATION (p. 232) PHOTOSYNTHESIS CELLULAR RESPIRATION Function Use energy from sun to make glucose Release energy from glucose to make ATP Cell Location Chloroplasts Mitochondria Occurs In Autotrophs Heterotrophs AND Autotrophs Reactants CO 2 + H 2 O + energy C 6 H 12 O 6 + O 2 Products C 6 H 12 O 6 + O 2 CO 2 + H 2 O + energy Overall Reaction CO 2 + H 2 O + energy → C 6 H 12 O 6 + O 2 → CO 2 + H 2 O + energy

C. Tracing Energy Flow n A. Trophic Levels - Each step in the pathway

C. Tracing Energy Flow n A. Trophic Levels - Each step in the pathway of energy flow is known as a __trophic level_. The first trophic level is always a ___producer____. The 2 nd trophic level is known as the primary (1 o) _consumer_ and may be an _herbivore__ or _omnivore_. The last step is always a _decomposer_. n 1. Food Chains – A food chain illustrates how energy is transferred by showing _feeding relationships between organisms. The arrows show the direction of _energy transfer – means “is eaten by”_.

Energy flows through an ecosystem in a series of steps in which organisms transfer

Energy flows through an ecosystem in a series of steps in which organisms transfer energy by being eaten ________ CONSUMERS (Heterotrophs) ↑ ↑ PRODUCERS _________ (Autotrophs) FOOD CHAIN = _________ http: //fig. cox. miami. edu/Faculty/Dana/foodchain. jpg

Typical Food Chain n Energy (Sun)____ → __Producer____ → _1˚ Consumer (herbivore or omnivore)____

Typical Food Chain n Energy (Sun)____ → __Producer____ → _1˚ Consumer (herbivore or omnivore)____ → _2˚ Consumer (carnivore or omnivore)____ → _Decomposer_ EX: Sun-> Grass->Grasshopper->Mouse->Snake->Hawk

n ·Which organism acts as a secondary consumer? n ·According to this food chain,

n ·Which organism acts as a secondary consumer? n ·According to this food chain, which organism could be n described as an herbivore? n ·Which organism is the producer? n ·What are two terms that could be used to describe the hawk?

Food Webs n 2. Food Webs – Typically feeding relationships are more complex than

Food Webs n 2. Food Webs – Typically feeding relationships are more complex than illustrated in a food chain. Most organisms eat _a variety of organisms and _are eaten by a variety of organisms. These interconnected pathways are more accurately shown in a food web.

n n n n According to this food web. . . ·How many different

n n n n According to this food web. . . ·How many different producers are there? ·Is the grasshopper a producer, primary, or secondary consumer? ·Is the grasshopper an herbivore, carnivore, or omnivore? ·What organism(s) acts as the decomposer? ·Give an example of an organism in this food web that acts as secondary and tertiary consumer. ·If all the squirrels in the community perished, would the hawk be able to survive? Explain. ·If the grass was destroyed, which organism would be most directly affected? Explain.

Ecological Pyramids n 3. Ecological Pyramids – Although in theory, a food _chain_ or

Ecological Pyramids n 3. Ecological Pyramids – Although in theory, a food _chain_ or food _web_ can consist of unlimited numbers of _trophic levels_, in actuality this does not take place. On average, only 10%_ of the energy stored in an organism is passed to the next trophic level. _90% of the energy is either used by the organism to maintain _homeostasis_or lost as _heat_to the environment. Because of this, most food chains typically consist of only _3 or 4 trophic levels. Ecologists use _pyramids to represent the amount of _energy_or _matter_at each _trophic level.

V. NUTRIENTS IN AN ECOSYSTEM (pp. 74 -80) n Unlike energy from the sun,

V. NUTRIENTS IN AN ECOSYSTEM (pp. 74 -80) n Unlike energy from the sun, nutrients are only available to an ecosystem in specific quantities and must be recycled_ within and between ecosystems. Nutrients may become a _limiting factor when they are depleted. Organisms require nutrients to _build biomolecules, cells, tissues, etc. Although all nutrients, including _water, are re-cycled, there a few nutrient cycles that are especially important.

A. Water Cycle

A. Water Cycle

B. Carbon Cycle n n Organisms require carbon to make _carbohydrates, _lipids_, _proteins_, and

B. Carbon Cycle n n Organisms require carbon to make _carbohydrates, _lipids_, _proteins_, and nucleic acids. Carbon dioxide in the atmosphere is taken up by _plants____ and _algae___ for _photosynthesis____. (Algae are autotrophic, unicellular organisms with cell walls made of cellulose and chloroplasts that belong to kingdom _Protista_). They produce glucose for _cellular respiration___. Humans and other _consumers___ eat plants & algae, or they eat other organisms who have eaten plants & algae. The carbon from glucose is returned to the atmosphere as _CO 2____, a waste product of cellular respiration. In addition, erosion, burning of _fossil fuels, and

Carbon Cycle

Carbon Cycle

4 main CARBON reservoirs in BIOSPHERE 1. In ______ atmosphere as CO 2 gas

4 main CARBON reservoirs in BIOSPHERE 1. In ______ atmosphere as CO 2 gas ocean 2. In _______ as dissolved CO 2 gas 3. On _______ in organisms, rocks, soil land Underground as coal & petroleum (fossil 4. _____ fuels) and calcium carbonate in rocks CO 2 in atmosphere Where does CO 2 in atmosphere come from? 1. Volcanic activity 2. Human activity (burning fossil fuels) 3. Cellular respiration 4. Decomposition of dead organisms CO 2 in Ocean BIOLOGY; Miller and Levine; Prentice Hall; 2006

C. Nitrogen Cycle n n Nitrogen Cycle – Organisms require nitrogen to build _

C. Nitrogen Cycle n n Nitrogen Cycle – Organisms require nitrogen to build _ proteins and nucleic acids. The _atmosphere__ is mostly nitrogen, but only _bacteria_ produce the _enzymes_ needed to convert nitrogen from the atmosphere to a useable form, a process known as _nitrogen fixation. After nitrogen fixation is carried out by bacteria in soil, the nitrogen compound in the soil is then absorbed by _plants__ and used to make _proteins & nucleic acids_. When other organisms _eat plants and algae_, they can re-use the nitrogen to build their own proteins_ and _nucleic acids_. When organisms die, _decomposers_ return the nitrogen to the soil where it may be taken up by _plants again or returned to the atmosphere by other _bacteria_.

Nitrogen Cycle

Nitrogen Cycle

Nitrogen Cycle n 79% of the atmosphere is made up of NITROGEN gas (N

Nitrogen Cycle n 79% of the atmosphere is made up of NITROGEN gas (N 2) BUT we can’t use the nitrogen gas we breathe! The bond in N 2 gas is so strong it can only be broken by: lightning Volcanic Activity Specialized bacteria

D. Phosphorus Cycle n D. Phosphorus Cycle - All organisms require phosphorus for DNA,

D. Phosphorus Cycle n D. Phosphorus Cycle - All organisms require phosphorus for DNA, RNA, lipids, and the phospholipid bilayer of the cell membrane. Phosphorus is found in soil and rocks, absorbed by the roots of plants, where it is transported through the rest of the plant by the xylem. Consumers eat plants, which is then returned to the soil

Phosphorus Cycle

Phosphorus Cycle

E. Nutrient Limitation n n E. Nutrient Limitation – When nutrients are scarce in

E. Nutrient Limitation n n E. Nutrient Limitation – When nutrients are scarce in an ecosystem, they are described as limiting nutrient. This imposes restrictions on the number of organisms, an organism’s growth, and the primary productivity of the system. For example, run-off from fertilized fields can trigger algae blooms in aquatic systems.

Algla Blooms

Algla Blooms

VIII. ECOLOGICAL SUCCESSION (pp. 94 -97) n n Ecosystems are constantly changing in response

VIII. ECOLOGICAL SUCCESSION (pp. 94 -97) n n Ecosystems are constantly changing in response to natural and human disturbances. As an ecosystem changes, older inhabitants gradually die out and new organisms move in, resulting in further changes in the community. Ecological succession refers to a series of slow changes that occur in a physical environment over time.

A. Primary Succession n n A. Primary Succession – Occurs following destruction of an

A. Primary Succession n n A. Primary Succession – Occurs following destruction of an ecosystem; for example, after Volcanic eruption, glaciers melting: First species to populate area known as pioneer species

Lichens: Pioneer Species n Lichens are the most common pioneer species after a volcano

Lichens: Pioneer Species n Lichens are the most common pioneer species after a volcano because they are capable of growing on bare rock. A lichen is a fungus and cyanobacteria living together. Cyanobacteria are photosynthetic bacteria. In a lichen, the cyanobacteria provides food for the fungus and the fungus provides water and protection for the cyanobacteria.

Primary Succession

Primary Succession

B. Secondary Succession n B. Secondary Succession – Occurs when a disturbance of some

B. Secondary Succession n B. Secondary Succession – Occurs when a disturbance of some kind changes an existing community without removing the soil; for example, wildfire, clearing land, plowing for farming.

Secondary Succession

Secondary Succession

IV. n ECOSYSTEM INTERACTIONS (pp. 90 -93) Ecosystems are influenced by a combination of

IV. n ECOSYSTEM INTERACTIONS (pp. 90 -93) Ecosystems are influenced by a combination of biological and physical factors. Together biotic factors and abiotic factors determine the health of an ecosystem and its _inhabitants_.

The Niche n A. The Niche - The role an organism plays in its

The Niche n A. The Niche - The role an organism plays in its _community is its _niche. An organism’s niche is comprised of _biotic_and _abiotic_factors, for example, the type of food it eats, how it obtains its food, the way it is food for other organisms, how & when it reproduces, its physical living requirements to survive, etc.

Warbler’s Niche

Warbler’s Niche

http: //www. electricwomen. com/hunterspoint/images/21 -street-sign-moreell. jpg HABITAT vs NICHE? Habitat is like an organism’s

http: //www. electricwomen. com/hunterspoint/images/21 -street-sign-moreell. jpg HABITAT vs NICHE? Habitat is like an organism’s address ______ Jellystone Park Niche is like an OCCUPATION organism’s _______ http: //resmedicinae. sourceforge. net/logos/doctor. png http: //www. michcampgrounds. com/yogibears/yogi-picnic-cartoon. jpg http: //www. formaui. org/kamalii/critters. htm

B. Interactions Within a Community interactions have a powerful effect on an ecosystem: n

B. Interactions Within a Community interactions have a powerful effect on an ecosystem: n 1. Competition – Competition occurs when organisms are attempting to use the same _resources at the same time. Each different species within a community must have its own _niche_.

NO TWO SPECIES CAN SHARE THE SAME NICHE IN THE SAME HABITAT ! Competitive

NO TWO SPECIES CAN SHARE THE SAME NICHE IN THE SAME HABITAT ! Competitive exclusion principle = _______________ BIOLOGY; Miller and Levine; Prentice Hall; 2006

Predation n 2. Predation – The organism that does the killing and eating is

Predation n 2. Predation – The organism that does the killing and eating is the _predator and the food organism is the _prey_.

3. Symbiosis – A relationship in which two organisms _live very closely together is

3. Symbiosis – A relationship in which two organisms _live very closely together is described as symbiosis. n n There are three main types of symbiotic relationships: a. Mutualism – Both organisms _benefit. For example, virtually all plant roots have mycorrhizae – a Fungus that resides within the plant roots. Fungus enhances absorption of water and nutrients in roots; plant provides protection for the fungus.

Commensalism n b. Commensalism – In commensalism, only one organism benefits, but the other

Commensalism n b. Commensalism – In commensalism, only one organism benefits, but the other organism _is not harmed. For example, barnacles are small _animals_that often attach themselves to whales. They do not harm the whales, and the barnacles benefit from the _movement of water as whale swims – provides food for barnacles.

Friendship

Friendship

n c. Parasitism – In parasitism, only one organism benefits and the other organism

n c. Parasitism – In parasitism, only one organism benefits and the other organism is _harmed__ by the relationship. The organism that is harmed is known as the _host__. Examples of parasites include _tapeworms, hookworms, ticks, lice.

V. n POPULATIONS WITHIN AN ECOSYSTEM (pp. 124 -127) Populations within an ecosystem cannot

V. n POPULATIONS WITHIN AN ECOSYSTEM (pp. 124 -127) Populations within an ecosystem cannot have unlimited growth. There are conditions that have an impact on population size known as _limiting factors. Limiting factors may described as density -dependent or density-independent.

A. Density-Dependent Limiting Factors n n n A. Density-Dependent Limiting Factors – Density-dependent factors

A. Density-Dependent Limiting Factors n n n A. Density-Dependent Limiting Factors – Density-dependent factors depend on population size; For example, _competition__ and availability of _food___, _water__, _sunlight, shelter & mates. Diseases and crowding. War, famine and disease for humans

B. Density-Independent Limiting Factors n n B. Density-Independent Limiting Factors– These are factors that

B. Density-Independent Limiting Factors n n B. Density-Independent Limiting Factors– These are factors that affect all populations the same way, regardless of size. Examples include _unusual weather, natural disasters__, and human activities such as _cutting down trees, damming rivers, etc…

SHORT SUPPLY If a nutrient is in _______ CYCLES SLOWLY OR _________ it will

SHORT SUPPLY If a nutrient is in _______ CYCLES SLOWLY OR _________ it will LIMIT the growth of the population LIMITING FACTOR = _______ During this drought, there was not enough food available and many kangaroos and cattle starved. http: //www. wspa-international. org/exhibition/gallery/large_Dead. Kenyan%20 drought. SPANA. jpg

C. Climax Community n n C. Climax Community– A climax community is a _stable

C. Climax Community n n C. Climax Community– A climax community is a _stable community with very little population growth or decline. Each ecosystem has a _carrying capacity_, a certain number of organisms that can exist _successfully_. When the carrying capacity is exceeded, resources become a _limiting factor_, and population numbers _decline_.