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Nuclear Chemistry

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Title: Nuclear Chemistry


1
Nuclear Chemistry
  • Chapter 10 Prentice Hall Physical Science

2
Review
  • All the chemistry weve discussed so far has
    involved electrons.
  • Questions
  • If element X has a molar mass of 3 g/mol and
    element Y has a molar mass of 5 g/mol, what must
    be the molar mass of X2Y?
  • If you tossed 128 coins in the air, about how
    many would you expect to land heads-up?
  • What do the mass number and atomic number
    represent?
  • Which subatomic particles are found in the
    nucleus?

3
Radioactivity
  • Antoine Henri Becquerel (1896) experimented with
    uranium salts and discovered radioactivity
  • Radioactivity (or nuclear decay) an unstable
    nucleus emits charged particles and energy
  • Radioisotope radioactive isotope - any atom that
    has an unstable nucleus. Examples
  • Uranium-238 (used in Becquerels experiment)
  • Carbon-14 (used often in radioactive dating)

4
Isotope symbology
  • Isotopes are named using the element name
    followed by the mass number (see examples, slide
    3)
  • The symbol for isotopes includes the element
    symbol, the mass number and the atomic number as
    follows

Mass on top
Atomic on bottom
5
3 Types of Nuclear Radiation
  • Nuclear radiation charged particles and energy
    that are emitted from the nuclei of radioisotopes

Radiation Type Symbol Charge Mass (amu) Common Source
Alpha particle a, 2 4 Radium-226
Beta particle b, 1- Carbon-14
Gamma ray g 0 0 Cobalt-60
6
Alpha Decay
  • Alpha particle, a
  • 2 protons and 2 neutrons
  • Positively charged
  • Same as He nucleus
  • Least penetrating type of nuclear radiation
  • Travel only centimeters in air
  • Can be stopped by a sheet of paper or clothing

7
Beta Decay
  • Beta particle, b
  • 1 electron
  • Negatively charged
  • Produced by a neutron that decomposes into a
    proton and an electron
  • More penetrating than a particles
  • Pass through paper
  • Stopped by a thin sheet of metal

8
Gamma Decay
  • Gamma ray, g
  • Penetrating ray of energy
  • Like X-rays and light, only very short wavelength
  • Most penetrating form of the three types
    discussed
  • Often accompanies alpha or beta decay
  • Several centimeters of lead or several meters of
    concrete required to stop it

9
Writing and Balancing Nuclear Reactions
  • Similar to chemical equations, but isotope
    symbols are used.
  • In a balanced nuclear equation
  • Mass on the left sum of mass s on the right
  • Atomic on the left sum of atomic s on the
    right
  • You will need to use your PERIODIC TABLES!

Reactants ? Products
10
Example Math Skills p. 295
  • Write a balanced nuclear equation for the alpha
    decay of polonium-210.
  • Step 1 Define reactants and products. Use
    letters to represent the unknown values.
  • Step 2 Write and solve equations to find unknown
    atomic and mass s.
  • Step 3 Look up the element symbol on the
    periodic table using the atomic .
  • Step 4 Write the balanced nuclear equation and
    double-check your solution.

Atomic 82 Pb (Lead)
11
Effects of Nuclear Radiation
  • Background radiation naturally occurring in the
    environment
  • Sources
  • Radioisotopes in air, water, rocks living
    things
  • Cosmic radiation
  • Generally at safe levels
  • Nuclear radiation can ionize atoms. At levels
    significantly above background, this can damage
    DNA and proteins
  • Which type of nuclear radiation is the least
    harmful? Which the most?

12
Detecting Nuclear Radiation
  • Geiger counters
  • Use gas-filled tubes to measure ionizing
    radiation
  • Gas produces an electric current when exposed to
    ionizing radiation
  • Film badges
  • Photographic film wrapped in paper
  • Film is exposed with exposure to radiation like
    photographic film is exposed with exposure to
    visible light

13
Rate of Nuclear Decay
  • Nuclear decay rate describes how fast nuclear
    changes take place
  • Unlike chemical reactions, nuclear decay rate
    does NOT vary with external conditions it is
    constant for a given radioisotope
  • Half-life the time required for half of a
    radioisotope sample to decay

14
Rates of Nuclear Decay (contd)
15
Rates of Nuclear Decay (contd)
  • Different radioisotopes have different half-lives
  • To determine how many half-lives have elapsed for
    a sample, divide the total time of decay by the
    half-life
  • Known decay rates are used in radioactive dating

Radioisotope Half-life
Radon-222 3.82 days
Iodine-131 8.07 days
Carbon-14 5730 years
Thorium-230 75,200 years
Uranium-238 4.47x109 years
16
Radiocarbon dating
  • Carbon-14 exists naturally in the atmosphere at a
    fairly constant ratio to C-12

CO2 absorbed while living (including some C-14)
Age of fossil determines by comparing C-14/C-12
ratio in fossil to atmospheric ratio
As C-14 decays, its replaced by C-14 absorbed
from atmosphere
Tree dies no more CO2 absorbed to replace
decaying C-14
17
Radiocarbon dating (contd)
  • Used for objects less that 50,000 years old
  • For older objects, must use different isotope
    with longer half-life
  • What isotopes would work well to date a rock
    formation that is thought to be close to a
    trillion years old?

18
Artificial Transmutation
  • Transmutation conversion of atoms of one element
    into atoms of another
  • Alchemists have attempted this for hundreds of
    years (but not through nuclear chemistry)
  • First artificial transmutation Ernest Rutherford
    (1919) turned nitrogen into oxygen-17

19
Artificial Transmutation (contd)
  • Transmutation achieved by bombarding atomic
    nuclei with high-energy particles
  • Protons, neutrons or alpha particles
  • Example Ernest Rutherfords transmutation used
    which particle?
  • Transuranium elements
  • Many produced by artificial transmutation of a
    lighter element
  • All are radioactive

20
Nuclear Forces
Strong nuclear forces
Electric forces
  • The strong nuclear force attracts protons and
    neutrons.
  • Stronger than electric forces over short
    distances
  • Decreases with distance (like gravity)
  • Electric repulsions push protons apart.
  • When a nucleus is large enough, the electric
    forces can overcome the strong nuclear forces.
  • Nuclei are unstable at this point.
  • Any atom with 83 or more protons is unstable
    and, therefore, radioactive.

Proton from a small nucleus
Small nucleus
Proton from a large nucleus
Large nucleus
21
Fission
  • Fission splitting of nucleus into two smaller
    parts
  • Lise Meitner, Fritz Strassman and Otto Hahns
    experiments (1939) first demonstrated nuclear
    fission.
  • A small amount of the original mass is converted
    into a lot of energy

22
Fission (contd)
  • About how much energy was released from 6.2 kg of
    Plutonium-239 in the second atomic bomb
    explosion? (Note Only about 1 kg underwent
    fission the rest was scattered.)

This quantity 2.5 x 1010 kWh, or enough energy
to power my house for over 3.6 million years!
23
Fission and Chain Reactions
  • Fission can result in a chain reaction.
  • Neutrons released from the first reaction can
    trigger another reaction, and so on similar to
    a rumor spreading.

Neutron
24
Chain Reactions (contd)
  • For a chain reaction to happen, each split
    nucleus must produce at least one neutron with
    enough energy to split another nucleus
  • This only happens when a specific mass of
    fissionable material is available called the
    critical mass.
  • Controlled chain reactions are used to generate
    electricity in nuclear power plants.
  • Uncontrolled chain reactions are used in nuclear
    weapons

25
Nuclear Fusion
  • Fusion nuclei of two atoms combine
  • The sun and other stars are powered by fusion of
    H into He
  • Requires extremely HIGH temperatures
  • What state is matter in at such high
    temperatures? PLASMA
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