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Title: Objective


1
Objective
  • Students will be able to analyze the laws of
    thermodynamics in order to illustrate the
    continuous flow of energy in the biosphere.

2
Chapter 3 Matter, Energy, Life
  • To the best of our knowledge, our Sun is the
    only star proven to grow vegetables. Philip
    Scherrer, Stanford University

3
Matter
  • All matter is composed of atoms of a certain
    number of elements.
  • Isotopes atoms of the same element with
    differing neutron numbers.
  • In Env. Sci. we focus on isotopes because they
    are often unstable, thus spontaneously emitting
    particles. Examples uranium plutonium can
    give us radioactive waste and nuclear energy.

4
Acids Bases
  • Acids (acidic) have an excess of H ions. pHlt7
  • Bases (alkaline) have an excess of OH- ions. pHgt7
  • Neutral (distilled H2O) equal balance of H and
    OH- ions. pH7
  • Acids cause environmental damage because the H
    ions react with living tissue and also nonliving
    substances like rocks or other land features that
    can erode under acid rain.

5
pH Scale
  • The pH Scale is LOGARITHMIC.
  • This means that each step on the scale is ten
    times more than the previous step.
  • For example, a pH of 2 is ten times more acidic
    than a pH of 3, and 100 times more acidic than a
    pH of 4.
  • Likewise a pH of 13 is ten times more alkaline
    than a pH of 12, and 100 times more alkaline than
    a pH of 11.

6
Buffers
  • A solutions pH can be neutralized by adding
    buffers.
  • For example, acid rain can be buffered by
    alkaline earth (rocks soil, predominantly
    limestone).

7
Energy
  • Energy the ability to do work examples heat,
    light, electricity, chemical energy, etc.
  • Kinetic energy energy of motion
  • Potential energy stored energy that is
    available for use. Examples food, gas.
  • Energy is measured in calories (heat) or joules
    (work).

8
Energy Quality
  • Low-quality energy that is diffused, dispersed,
    and low in temperature. Example the heat
    energy stored in the oceans.
  • High-quality energy that is intense,
    concentrated, and high in temperature used to
    carry out work. Examples fire, electricity, oil
  • Many alternative energy sources are low-quality
    compared to the high-quality energy sources we
    have become accustomed to (oil, gas, electricity,
    coal).

9
Thermodynamics Energy Transfers
  • Thermodynamics deals with how energy is
    transferred in natural processes deals with the
    rates of flow and the transformation of energy
    from one form or quality to another.
  • Energy conversions underlie all ecological
    processes.

10
Laws of Thermodynamics
  • First Law - Matter can be neither created nor
    destroyed, only reused over time. (Also known as
    the Law of Conservation of Matter)
  • Second Law With each successive energy transfer
    or transformation in a system, less energy is
    available to do work i.e., every time energy is
    used is to do work, some of that energy is
    dissipated or lost as heat.
  • The Second Law results in increased entropy,
    meaning that everything in the universe tends to
    fall apart, slow down, and get more disorganized
    with time (including humans!!).

11
Energy for Life
  • Nearly all life on Earth depends on the sun for
    energy to create cells and carry out life
    processes.
  • Exceptions to this rule are chemosynthetic
    bacteria which oxidize hydrogen sulfide for
    energy. This process can support entire living
    systems deep in the ocean, beyond the reach of
    sunlight.

12
Solar Energy Sun
  • Essential to life for two reasons
  • 1. provides warmth (Earths water atmosphere
    help to moderate, maintain, and distribute the
    suns heat.)
  • 2. provides light (solar radiation)
    photosynthesis converts solar radiation into
    useful, high quality chemical energy in the form
    of glucose.

13
Solar Calculations
  • How much of the available solar energy is
    actually used by organisms?
  • The amount of incoming solar radiation is about
    1,372 W/m2 at the top of the atmosphere (1
    watt1J/s). However, more than ½ may be
    reflected or absorbed by clouds, dust, and gases
    (ozone) in the atmosphere.
  • Of the solar radiation that reaches Earth, about
    10 is UV, 45 is visible light, and 45 is
    infrared (heat). The majority of this is either
    absorbed by land and water or reflected by snow
    and ice.
  • Of all the visible light that reaches Earth,
    plants can only use red and blue light for
    photosynthesis, which amounts to only 1 to 2 of
    all sunlight falling on plants. This small
    percentage represents the energy base for
    virtually all life in the biosphere!

14
Photosynthesis vs. Cellular Respiration
  • 6H2O 6CO2 light (energy)
    C6H12O6 6O2 process of making glucose
    energy is captured
  • C6H12O6 6O2 6H2O 6CO2
    energy process of using glucose energy is
    released

15
What is an Ecosystem?
  • Consists of a collection of organisms and all the
    physical aspects of their habitat, such as the
    soil, water, and weather.
  • Population- all the members of a species living
    in a given area at the same time.
  • Community all the populations living and
    interacting in a particular area.
  • Ecosystem composed of a biological community
    and its physical environment (includes biotic
    abiotic factors).
  • Most ecosystems are open, i.e., they exchange
    materials organisms with other ecosystems.
    Example stream, river
  • Closed ecosystem very little enters or leaves.
    Example - aquarium

16
How does Photosynthesis Provide the Energy that
Drives all Ecosystems?
  • Plants capture some of the suns light and store
    it as chemical energy in organic molecules.
  • This is what we call food, i.e. fruits veggies.
    A scientific term is Primary Productivity.
  • Critical Thinking How does primary productivity
    determine the amount of energy available in an
    ecosystem?

17
Productivity, or Biomass
  • Biomass the amount of biological material
    produced in a given area during a given period of
    time.
  • Primary Productivity producers or autotrophs
  • Secondary Productivity consumers or
    heterotrophs
  • Gross Primary Productivity the total amount of
    energy that producers fix a percentage of this
    is used for the maintenance needs of the
    producers themselves
  • Net primary productivity - the energy available
    to other trophic levels

18
What is a Food Chain?
  • A Food Chain Illustrates how Energy is
    Transferred among Organisms in an Ecosystem.

19
What is a Food Web?
  • In most ecosystems, energy doesnt follow simple,
    straight paths because individual organisms feed
    on multiple sources.
  • These connections can be represented in a Food
    Web.
  • Next slide, then Borneo story.

20
How are Food Webs both Simple Complex?
21
Who eats what?!?
  • Herbivores plant eaters ex. - cows
  • Carnivores meat eaters ex. - wolves
  • Omnivores eat both plants and meat ex.
    humans, bears
  • Scavengers clean up dead carcasses of larger
    animals ex. crows, vultures, hyenas
  • Detritivores consume litter, debris, and dung
    ex. ants, beetles, copepods
  • Decomposers breakdown and recycle organic
    matter ex. fungi and bacteria

22
What is an Energy Pyramid How does it Represent
different Trophic Levels?
  • Illustrates the amount of energy transferred in
    an ecosystem.
  • Each block of the Energy Pyramid represents a
    unique Trophic Level.

23
Energy is Limited
  • Available energy decreases at each level, because
    at every trophic level energy is lost as heat.
  • 10 rule Each block of the pyramid can only
    obtain 10 of the energy below it.
  • Why? Some of the food that organisms eat is
    undigested and doesnt provide usable energy.
    Also, some is used in the daily process of
    surviving or lost as heat and so cant be eaten
    as biomass by a higher trophic level.

24
Objective Drill
  • Students will demonstrate that matter cycles
    through and between living systems and the
    physical environment in order to show how energy
    is constantly being recombined in different ways.
  • Your body contains vast numbers of carbon atoms.
    How is it possible that some of these carbon
    atoms may have been part of the body of a
    prehistoric creature?

25
How are Matter and Energy Recycled in an
Ecosystem?
  • Nutrients are substances needed by the body for
    energy, growth, maintenance.
  • Five very important Nutrients are Water, Carbon,
    Nitrogen, Phosphorus, Sulfur.
  • These Nutrients are Recycled through
    Biogeochemical Pathways
  • Hydrologic Cycle
  • Carbon Cycle
  • Nitrogen Cycle
  • Phosphorus cycle
  • Sulfur Cycle

26
The Hydrologic Cycle (H2O)
27
The Water Cycle Contd
  • Solar energy evaporates H2O from seas and land
  • Winds distribute water vapor around the globe
  • Condenses into clouds
  • Water precipitates over land and oceans
  • Precipitation and Runoff from land enters Lakes
    Rivers
  • Returns to ocean
  • Precipitation enters Groundwater through
    Percolation
  • Water enters animals through drinking and eating,
    and returns to the atmosphere through exhalation
    and sweating

28
The Carbon Cycle
29
Carbon Cycle Contd
  • Carbon is the key ingredient in all living
    organisms.
  • CO2 is released into the atmosphere by
  • volcanic activity
  • respiration
  • the burning of fossil fuels
  • the decomposition of organic matter.
  • Plants then take up this CO2 in photosynthesis.
    Animals obtain carbon by eating plants.
  • Plants and animals release CO2 through
    respiration.

30
Carbon Cycle Continued
  • The carbon atoms in coal and oil arent released
    until it is burned for fuel.
  • Enormous amounts of carbon are locked up as CaCO3
    (calcium carbonate) in the shells of aquatic
    organisms. Eventually, this will probably become
    limestone.
  • Therefore, the ocean is considered a carbon sink
    because it removes carbon from the atmosphere,
    thus reducing green-house gases.
  • Huge forests are also carbon sinks.

31
Human Interactions with the Carbon Cycle
  • The burning of fossil fuels and the act of
    deforestation have released an abundance of
    carbon back into the atmosphere.
  • This excess of atmospheric carbon is a greenhouse
    gas and results in global warming, which in turn
    has adversely affected global weather patterns,
    i.e., more intense storms, heat waves, drought,
    flooding, and even the eventual melt of the polar
    ice caps.
  • By working toward the goal of sustainable
    development, we can limit the amount of carbon
    re-released into the atmosphere and slow the
    process of global warming.

32
The Nitrogen Cycle
  • http//www.mhhe.com/biosci/genbio/tlw3/eBridge/Chp
    29/animations/ch29/1_nitrogen_cycle.swf

33
Nitrogen
  • Nitrogen is the most abundant element in the
    atmosphere, existing as a gas (N2). The
    atmosphere is the primary sink for nitrogen.
  • However, most plants can only use Nitrogen in the
    form of Nitrate (NO3-).
  • Nitrogen Fixation (the process of combining
    nitrogen with Hydrogen to form Ammonia, NH3) is
    accomplished by Lightning and by Bacteria that
    live in soil and in the roots of certain plants
    (legumes).
  • This ammonia is then converted, or oxidized, to
    nitrite and then to nitrate by bacteria in a
    process called Nitrification.
  • Now, it is in a form that plants can use.

34
Nitrogen Contd
  • Plants then absorb Nitrogen through the soil with
    the help of the Nitrogen Fixing Bacteria and use
    it for making chlorophyll.
  • Animals, including humans, obtain Nitrogen by
    Eating Plants and other Animals that contain
    Nitrogen.
  • We use nitrogen for making proteins and DNA.

35
Nitrogen Contd
  • Decomposers (fungi bacteria) break down
    decaying animals and thereby release Nitrogen as
    Ammonia (NH3). Again, this process is called
    Nitrogen Fixation.
  • Then, denitrifying bacteria in the soil take up
    the ammonia and oxidize it into nitrites (NO2-)
    and nitrates (NO3-). Again, this is called
    Nitrification. In this way, it is ready for reuse
    by plants.
  • In the reverse process, Denitrification,
    Nitrogen is converted from NO3- and NO2- to N2,
    and returned to the atmosphere as a gas.

36
Problems with Nitrogen
  • By using nitrate-rich synthetic fertilizers,
    cultivating nitrogen-fixing crops, and burning
    fossil fuels, we have more than doubled the
    amount of nitrogen cycling through our
    environment.
  • This causes a loss of soil nutrients (calcium and
    potassium).
  • Acidification of rivers and lake
  • Rising concentrations of the greenhouse gas
    nitrous oxide.
  • It also encourages the spread of weeds into areas
    occupied by native plant species adapted to
    nitrogen-poor environments.
  • Nitrogen-rich runoff causes toxic algal and
    dinoflagellate blooms.

37
The Phosphorus Cycle
38
Phosphorus Continued
  • Begins when phosphorus is leeched from rocks and
    minerals over long periods of time.
  • Usually transported in aqueous form because,
    unlike nitrogen, it has no atmospheric form.
  • It is then taken in by produces and consequently
    eaten by consumers, and finally rereleased
    through decomposition.

39
Phosphorus Cycle
  • Energy-rich, phosphorus-containing compounds are
    primary participants in energy transfer reactions
  • The amount of available phosphorus in an
    environment can have a dramatic effect on
    productivity, therefore it is termed a limiting
    factor.
  • The phosphorus cycle takes an inordinate amount
    of time to complete. Ex. deep sediments of the
    oceans and lithosphere are significant phosphorus
    sinks of extreme longevity. Phosphate ores that
    are now being mined for fertilizers represent
    exposed ocean sediments that are millennia old.
  • Phosphates can be found in everyday household
    cleaners like laundry and dish soaps. When this
    water reaches lakes, streams, and/or oceans, the
    abundance of phosphorus stimulates plant,
    photosynthetic bacteria, and algal growth, making
    it a major contributor to water pollution.

40
The Sulfur Cycle
41
Sulfur Cycle
  • Most of the earths sulfur is tied up underground
    in rocks and minerals such as pyrite (iron
    disulfide) or gypsum (calcium sulfate).
  • It is released into the atmosphere by the process
    of weathering and erosion, emissions from deep
    sea vents, volcanic eruptions.
  • Bacteria also sequester sulfur in biogenic
    deposits or release it into the environment,
    depending on oxygen concentrations, pH and light
    levels.
  • Humans release vast amounts of sulfur through the
    burning of fossil fuels. These are termed
    anthropogenic emissions, meaning created by
    humans.
  • Complicated by the large number of oxidation
    states that the sulfur element can assume, i.e.,
    H2S, SO2, SO4-2, elemental sulfur, to name a
    few.

42
Sulfur Continued
  • Can produce
  • acid rain
  • human health problems
  • damage to buildings
  • damage to vegetation
  • reduced visibility
  • cloud cover that cools cities and may be slightly
    offsetting greenhouse effects of rising CO2
    concentrations.

43
Biogeochemical Contaminants
  • Any or all of the elements and compounds of the
    biogeochemical cycles can cause EUTRIFICATION of
    aquatic areas.
  • Eutrification rivers, lakes, streams, etc. that
    have become rich in organic matter to the point
    of oxygen depletion.

44
Exit Ticket
  • Choose one of the Material Cycles (carbon,
    nitrogen, phosphorus, or sulfur) and identify the
    components of the cycle in which you participate.
    For which of these components would it be
    easiest to reduce your impacts?
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