1. G. Tyler Miller’s Living in the Environment 13th Edition Chapter 3
Science, Systems, Matter,
and Energy

2. Key Concepts Science as a process for understanding
Components and regulation of systems
Matter: forms, quality, and how it changes; laws of matter
Energy: forms, quality, and how it changes; laws of energy
Nuclear changes and radioactivity

3. Science, and Critical Thinking
Scientific data
Facts
Scientific hypothesis
Explanation of what is observed in nature
Scientific (natural) laws
Scientific theories
Consensus science
Data, theories, and laws that widely accepted by the scientific community
Frontier science
Preliminary results
Ask a question
Do experiments
and collect data
Formulate
hypothesis
to explain data
Do more
Experiments to
test hypothesis
Revise hypothesis
if necessary
Well-tested and
accepted
hypotheses
become
scientific theories
Interpret data
accepted patterns
In data become
scientific laws
Fig. 3-2 p. 41

4. Formulate a Hypothesis
Scientific Method
Make Observations
Formulate a Hypothesis
Test Hypothesis
Collect Data
Interpret Data
Draw Conclusions

5. Controlled Experiment (Single Variable Analysis)
Experimental Group
Variables change in a known way
Independent variable
Dependent Variable
Control Group (Controls)
Variables are not changed
Controls
Constants
Data
Quantitative - numbers
Qualitative - descriptions

6. Types of Reasoning Inductive reasoning Deductive reasoning
Using specific observations and measurements to arrive at a general conclusion
bottom-up reasoning
Deductive reasoning
Reasoning that goes from the general to the specific
top-down reasoning

7. Models and Behavior of Systems
System – a set of components that
function in a regular and predictable manner
can be isolated for observation and study

8. Models and Behavior of Systems
Inputs
matter, energy, information
Flows
throughputs of matter, energy, or information at certain rates
Stores
storage areas for matter, energy or information
Outputs
Form of matter, energy, or information that flow out of the system and into sinks in the environment

9. Models Approximate representations or simulations of real systems to
find out how systems work
evaluate which ideas or hypotheses work
Mental models – what do you think
Mathematical models – one or more equations
To describe the behavior of a system
Make predictions about the behavior of a system
Conceptual models
Qualitative
Numerical models
Computer simulations

10. System Regulation
Feedback loop – when output of matter, energy, or information is fed back into the system as an input that changes the system.
Positive Feedback – causes change in the same direction
Negative Feedback – one change leads to a lessoning of that change.
Coupled loops

11. System Regulation
Homeostasis – maintenance of a favorable internal condition of a system despite external changes.
Time Delay – delay in expected effect
Synergy – the combined effect of two or more processes is greater than the sum of the separate effects
Fig. 3-3 p. 46

13. Matter: Forms, Structure, and Quality
Elements
Building blocks of matter
Compounds
Two or more different elements held together by chemical bonds
Mixtures
Combinations of various elements, compounds, or both
Molecules
Two or more atoms of the same or different elements held together by chemical bonds
Example: O2
Matter – anything that has mass and takes up space.
Two chemical forms – elements and compounds

14. Atom – the smallest unit of matter that is unique to a particular element.
Subatomic Particles
Protons
Positively charges
Neutrons
uncharged
Electrons
Negatively charged

15. Atomic Characteristics
Atomic Number
Number of protons in the nucleus
Atomic Mass
Number of protons and neutrons
Ions
Atoms that have lost or gained electrons
Isotopes
Forms of a element having the same atomic number but a different mass number
Identified by attaching their mass number to their name
U235

16. Examples of Atoms
Fig. 3-4 p. 48

17. Chemical Bonds
Chemical formulas show the number of atoms of each type in a compound
Contains symbol for each element
Uses subscripts to represent the number of atoms
Ionic bonds
Bonds between oppositely charged ions
NaCl (Na+ and Cl-)

18. Chemical Bonds Covalent bonds – bonds between uncharged atoms
H2O
Hydrogen bonds
Weak attraction between molecules of covalent compounds

19. Organic vs Inorganic Compounds
contain carbon atoms
Held together by covalent bonds
Hydrocarbons
Carbon and hydrogen
methane (CH3)
Chlorinated hydrocarbons
Carbon, hydrogen, and chlorine
DDT (C14H9Cl5)
Chlorofluorocarbons (CFCs)
Carbon, chlorine, and flourine
freon (CCl2F2)

20. Organic Compounds Simple carbohydrates Complex carbohydrates Proteins
Carbon, hydrogen, oxygen
Simple sugars (C6H12O6)
Complex carbohydrates
Two or more simple sugars hooked together
Proteins
Monomers of amino acids linked together

21. Genetic Material Nucleic Acids
DNA and RNA
Genes – specific sequence of nucleotides in a DNA molecule
Fig. 3-6 p. 50

22. Organic vs Inorganic Compounds
Lack carbon-carbon or carbon-hydrogen covalent bonds
NaCl, H2O, N2O, CO2, NH3

23. The Four States of Matter
Solid
Liquid
Gas
Plasma
Fig. 3-7 p. 50

24. The Four States of Matter
Plasma
high energy mixture of positively charged ions and negatively charged electrons
sun, stars, lightening

25. Matter Quality and Material Efficiency
High-quality matter
Concentrated
Near the earth’s surface
Great potential for use
Low-quality matter
Dilute
Deep underground
Little potential as a resource
Material efficiency (resource productivity)
Total amount of material needed to produce each unit of goods and services

26. Energy: What is it?
The capacity to do work and transfer heat.
Work = force x distance

27. Energy: Forms Kinetic energy Potential energy
Energy contained in moving objects
Wind, streams, electricity
Potential energy
Stored energy
Stick of dynamite, water behind a dam

28. Electromagnetic radiation
Energy radiated in the form of waves as a result of changing electric and magnetic fields
Fig. 3-9 p. 52
Ionizing radiation – has enough energy to knock electrons from atoms and change them to positively charged ions.
The resulting highly reactive electrons and ions can
Disrupt living cells
Interfere with body processes
Cause many types of sickness, including cancer

29. Heat Energy Heat Temperature
The total kinetic energy of all the moving atoms, ions, or molecules within a given substance
Temperature
Average speed of motion of the atoms, ions, or molecules in a sample of matter at a given moment

30. Transfer of Heat Energy
Convection
Conduction
Radiation
Heat from a stove burner causes
atoms or molecules in the pan’s
bottom to vibrate faster. The vibrating
atoms or molecules then collide with
nearby atoms or molecules, causing
them to vibrate faster. Eventually,
molecules or atoms in the pan’s
handle are vibrating so fast it
becomes too hot to touch.
As the water boils, heat from the hot
stove burner and pan radiate into the
surrounding air, even though air
conducts very little heat.
Heating water in the bottom of a pan
causes some of the water to vaporize
into bubbles. Because they are
lighter than the surrounding water,
they rise. Water then sinks from the
top to replace the rising bubbles.This
up and down movement (convection)
eventually heats all of the water.
Fig p. 553

31. Energy: Quality High-quality energy concentrated Low-quality energy
dispersed
Fig p. 53

32. Physical and Chemical Changes

34. Matter only changes form
The Law of Conservation of Matter: matter is neither created nor destroyed
Matter is not consumed
Matter only changes form
There is no “away”

35. How harmful are pollutants?
Chemical nature of pollutants
Concentration
Persistence
Degradable (nonpersistent) pollution
Broken down completely by natural, chemical or biological processes
Slowly degradable (persistent) pollution
May take decades or longer
DDT
Nondegradable pollutants
Cannot be broken down
Lead, mercury, arsenic

36. Nuclear Changes – nuclei of isotopes spontaneously change
Natural radioactive decay
Unstable isotopes spontaneously emit fast-moving particles, high energy radiation, or both at fixed rates
“radioisotopes”
Damaging “ionizing” radiation
Fig p. 56

37. Ionizing Radiation Gamma rays Alpha particles Beta particles
High-energy electromagnetic radiation
Alpha particles
Fast moving, positively charged chunks of matter
Beta particles
High speed electrons
Fig p. 56

38. Ionizing Radiation: Effects
Genetic Damage
Mutations or changes in DNA that alter genes and chromosomes
Somatic Damage to tissue
Burns, eye cataracts, certain cancers
Fig p. 56

39. Nuclear Changes Radioactive Decay
Radioactive isotopes decay at a characteristic fixed rate called a half-life (t1/2)
Time for half the nuclei in a sample to decay
Can’t be changed due to T, P, or chemical rxns
Used to estimate time a sample of radioisotope must be stored safely before it decays to a safe level half-life X 10

40. Radioactive Decay and Half-life
Half-Lives of Selected Radioisotopes
Isotope
Radiation Half-Life
Emmitted
Potassuium-42
12.4 hrs
Alpha, beta
Iodine-131
8 days
Beta, gamma
Colbalt-60
5.27 yrs
Hydogren-3 tritium
12.5 yrs
Beta
Strontium-90
28 yrs
Carbon-14
5,370 yrs
Plutonium-239
24,000 hrs
Alpha, gamma
Uranium-235
710 million yrs
Uranium-238
4.5 billion yrs
Time needed for one-half of the nuclei in a radioisotope to emit its radiation (decay)
Characteristic half-life for each radioisotope
General rule: radioisotopes must be stored for 10 half-lives

41. Nuclear Reactions
Fission
Fig p. 57
Fusion
Fig p. 58

42. Nuclear Changes Nuclear Fission
Fission—splitting of nuclei
Nuclei of isotopes with large masses split into lighter nuclei when struck by neutrons
Release energy and more neutrons setting off a chain reaction
Atomic bomb and nuclear power plants

43. 235 92 U n 92 36 Kr
235 92 n U
235 92 n U n
141 56 Ba 92 36 Kr n 92 36 Kr n n n n
235 92 U n
141 56 Ba 92 36 Kr
141 56 n Ba
235 92 U n
235 92 U n
141 56 Ba
235 92 U

44. Nuclear Changes Nuclear Fusion
Fusion—joining of nuclei
Isotopes of light elements are forced together at high T’s until they fuse into a heavier nucleus
Harder to accomplish than fission, but releases more energy
Fusion of H nuclei to form He nuclei is a source of energy for sun and stars
H bombs

45. Fuel
Reaction Conditions
Products
D-T Fusion +
Neutron
Hydrogen-2 or
deuterium nucleus +
Energy + + + +
100 million ˚C
Helium-4
nucleus
Hydrogen-3 or
tritium nucleus +
Proton
Neutron

46. Laws Governing Energy Changes
First Law of Thermodynamics (Energy)
Energy is neither created nor destroyed
Energy only changes form
You can’t get something for nothing
ENERGY IN = ENERGY OUT

47. Laws Governing Energy Changes
Second Law of Thermodynamics
In every transformation, some energy is converted to heat
You cannot break even in terms of energy quality

48. Mechanical
energy
(moving,
thinking,
living)
Chemical
energy
(photosynthesis)
Chemical
energy
(food)
Solar
energy
Waste
heat
Waste
heat
Waste
heat
Waste
heat

49. Connections: Matter and Energy Laws and Environmental Problems
High-throughput (waste) economy
Matter-recycling economy
Low-throughput economy
Fig p. 60; see Fig p. 61