Chapter 21 Nuclear Chemistry - PowerPoint PPT Presentation

1 / 79
About This Presentation
Title:

Chapter 21 Nuclear Chemistry

Description:

Chemistry, The Central Science, 10th edition Theodore L. Brown; H. Eugene LeMay, Jr.; and Bruce E. Bursten Chapter 21 Nuclear Chemistry John D. Bookstaver – PowerPoint PPT presentation

Number of Views:134
Avg rating:3.0/5.0
Slides: 80
Provided by: JohnB392
Category:

less

Transcript and Presenter's Notes

Title: Chapter 21 Nuclear Chemistry


1
Chapter 21Nuclear Chemistry
Chemistry, The Central Science, 10th
edition Theodore L. Brown H. Eugene LeMay, Jr.
and Bruce E. Bursten
John D. Bookstaver St. Charles Community
College St. Peters, MO ? 2006, Prentice Hall, Inc.
2
February 3
  • Nuclear chemistry
  • HW
  • 1,2,3,7,11,13,17,19,27,29 for tomorrow
  • 31 to35 odd, 41,57,59,61

3
The Nucleus
  • Remember that the nucleus is comprised of the two
    nucleons, protons and neutrons.
  • The number of protons is the atomic number.
  • The number of protons and neutrons together is
    effectively the mass of the atom.

4
Isotopes
  • Not all atoms of the same element have the same
    mass due to different numbers of neutrons in
    those atoms.
  • There are three naturally occurring isotopes of
    uranium
  • Uranium-234
  • Uranium-235
  • Uranium-238

5
(No Transcript)
6
Radioactivity
  • It is not uncommon for some nuclides of an
    element to be unstable, or radioactive.
  • We refer to these as radionuclides.
  • There are several ways radionuclides can decay
    into a different nuclide.

7
Types ofRadioactive Decay
8
(No Transcript)
9
SeparationAlphaBetaGamma.MOV Separation of
Radiation
10
(No Transcript)
11
(No Transcript)
12
(No Transcript)
13
Nuclear Reactions
  • The chemical properties of the nucleus are
    independent of the state of chemical combination
    of the atom.
  • In writing nuclear equations we are not concerned
    with the chemical form of the atom in which the
    nucleus resides.
  • It makes no difference if the atom is as an
    element or a compound.
  • Mass and charges MUST BE BALANCED!!!

14
Alpha Decay
  • Loss of an ?-particle (a helium nucleus)

15
Alpha Decay
  • Mass changes by 4
  • The remaining fragment has 2 less protons
  • Alpha radiation is the less penetrating of all
    the nuclear radiation (it is the most massive
    one!)

16
Beta Decay
  • Loss of a ?-particle (a high energy electron)

17
Beta Decay
  • Involves the conversion of a neutron in the
    nucleus into a proton and an electron.
  • Beta radiation has high energies, can travel up
    to 300 cm in air.
  • Can penetrate the skin

18
Beta decay
  • Write the reaction of decay for C-14

19
Gamma Emission
  • Loss of a ?-ray (high-energy radiation that
    almost always accompanies the loss of a nuclear
    particle)

20
Positron Emission
  • Loss of a positron ( particle with same mass,
    but opposite charge than an electron)

21
Positron emission
  • Involves the conversion of a proton to a neutron
    emitting a positron.
  • The atomic number decreases by one, mass number
    remains the same.

22
Electron Capture (K-Capture)
  • Capture by the nucleus of an electron from the
    electron cloud surrounding the nucleus.
  • As a result, a proton is transformed into a
    neutron.

23
Electron capture
  • Rb-81
  • Note that the electron goes in the side of the
    reactants. Electron gets consumed.

24
Patterns of nuclear Stability
  • Any element with more than one proton ( all but
    hydrogen) will have repulsions between the
    protons in the nucleus.
  • A strong nuclear force helps keep the nucleus
    from flying apart.

25
Neutron-Proton Ratios
  • Neutrons play a key role stabilizing the nucleus.
  • The ratio of neutrons to protons is key to
    determine the stability of a nucleus .

26
Neutron-Proton Ratios
  • As nuclei get larger, it takes a greater number
    of neutrons to stabilize the nucleus.

27
Neutron-Proton Ratios
  • For smaller nuclei (Z ? 20) stable nuclei have a
    neutron-to-proton ratio close to 11.

28
Stable Nuclei
  • The shaded region in the figure shows what
    nuclides would be stable, the so-called belt of
    stability.

29
Stable Nuclei
  • Nuclei above this belt have too many neutrons.
  • They tend to decay by emitting beta particles. (
    neutron becomes proton )

30
Above the belt of stabilityBeta particle emission
  • Too many neutrons. The nucleus emits Beta
    particles, decreasing the neutrons and increasing
    the number of protons.

31
Stable Nuclei
  • Nuclei below the belt have too many protons.
  • They tend to become more stable by positron
    emission or electron capture (both lower the
    number of protons)

32
Stable Nuclei
  • Elements with low atomic number are stable if
    proton neutrons
  • There are no stable nuclei with an atomic number
    greater than 83.
  • These nuclei tend to decay by alpha emission.

33
Below the stability beltIncrease the number of
neutrons (by decreasing protons)
  • Positron emission more common in lighter nuclei.
  • Electron capture common for heavier nuclei.

34
(No Transcript)
35
Radioactive Series
  • Large radioactive nuclei cannot stabilize by
    undergoing only one nuclear transformation.
  • They undergo a series of decays until they form a
    stable nuclide (often a nuclide of lead).

36
Predicting modes of nuclear decay
  • C-14
  • Xe-118
  • Pu-239
  • In-120

37
  • beta decay
  • Positron emission or electron capture
  • Alpha decay (too heavy, loses mass)
  • Beta decay (ratio too low, gains protons)

38
MAGIC NUMBERS 2, 8, 20, 28, 50, or 82
  • Nuclei with 2, 8, 20, 28, 50, or 82 protons or
    2, 8, 20, 28, 50, 82, or 126 neutrons tend to be
    more stable than nuclides with a different number
    of nucleons.

39
Some Trends
  • Nuclei with an even number of protons and
    neutrons tend to be more stable than nuclides
    that have odd numbers of these nucleons.

40
Shell model of the nucleus
  • Nucleons are described a residing in shells like
    the shells for electrons.
  • The numbers 2,8,18,36,54,86 correspond to closed
    shells in nuclei.
  • Evidence suggests that pair of protons and pairs
    of neutrons have special stability

41
Transmutations
  • To change one element into another.
  • Only possible in nuclear reactions never in a
    chemical reaction.
  • In order to modify the nucleus huge amount of
    energy are involved.
  • These reactions are carried in particle
    accelerators or in nuclear reactors

42
Nuclear transmutations
  • Alpha particles have to move very fast to
    overcame electrostatic repulsions between them
    and the nucleus.
  • Particle accelerators or smashers are used. They
    use magnetic fields to accelerate the particles.

43
Particle Accelerators(only for charged
particles!)
  • These particle accelerators are enormous, having
    circular tracks with radii that are miles long.

44
Cyclotron
  • Nuclear transformations can be induced by
    accelerating a particle and colliding it with the
    nuclide.

45
Neutrons
  • Can not be accelerated. They do not need it
    either (no charge!).
  • Neutrons are products of natural decay, natural
    radioactive materials or are expelled of an
    artificial transmutation.
  • Some neutron capture reactions are carried out in
    nuclear reactors where nuclei can be bombarded
    with neutrons.

46
Representing artificial nuclear transmutations
  • 14N 4He ? 7O 1H
  • Target nucleus ( bombarding particle, ejected
    particle ) product nucleus
  • 14N (a, p) 17O
  • Write the balanced nuclear equations summarized
    as followed
  • 16 O ( p, a) N
  • 27Al (n, a)24 Na

47
Measuring Radioactivity
  • One can use a device like this Geiger counter to
    measure the amount of activity present in a
    radioactive sample.
  • The ionizing radiation creates ions, which
    conduct a current that is detected by the
    instrument.

48
Mass defect
  • The mass of the nucleus is always smaller than
    the masses of the individual particles added up.
  • The difference is the mass defect.
  • That small amount translate to huge amounts of
    energy ?E (?m) c2
  • That energy is the Binding energy of the nucleus,
    and is the energy needed to separate the nucleus.

49
Energy in Nuclear Reactions
  • For example, the mass change for the decay of 1
    mol of uranium-238 is -0.0046 g.
  • The change in energy, ?E, is then
  • ?E (?m) c2
  • ?E (-4.6 ? 10-6 kg)(3.00 ? 108 m/s)2
  • ?E -4.1 ? 1011 J This amount is 50,000 times
    greater than the combustion of 1 mol of CH4

50
Types of nuclear reactionsfission and fusion
  • The larger the binding energies, the more stable
    the nucleus is toward decomposition.
  • Heavy nuclei gain stability (and give off energy)
    if they are fragmented into smaller nuclei.
    (FISSION)

51
  • Even greater amounts of energy are released if
    very light nuclei are combined or fused together.
    (FUSION)

52
Nuclear Fission
  • How does one tap all that energy?
  • Nuclear fission is the type of reaction carried
    out in nuclear reactors.

53
Nuclear Fission
  • Bombardment of the radioactive nuclide with a
    neutron starts the process.
  • Neutrons released in the transmutation strike
    other nuclei, causing their decay and the
    production of more neutrons.

54
Nuclear Fission
  • This process continues in what we call a nuclear
    chain reaction.

55
Nuclear Fission
  • If there are not enough radioactive nuclides in
    the path of the ejected neutrons, the chain
    reaction will die out.

56
Nuclear Fission
  • Therefore, there must be a certain minimum
    amount of fissionable material present for the
    chain reaction to be sustained Critical Mass.

57
Controlled vs Uncontrolled nuclear reaction
  • Controlled reactions inside a nuclear power
    plant
  • Uncontrolled reaction nuclear bomb

58
Nuclear Reactors
  • In nuclear reactors the heat generated by the
    reaction is used to produce steam that turns a
    turbine connected to a generator.

59
Nuclear Reactors
  • The reaction is kept in check by the use of
    control rods.
  • These block the paths of some neutrons, keeping
    the system from reaching a dangerous
    supercritical mass.

60
FUSION
  • Combining small nucleii to form a larger one.
  • Require millions of K of temperature

61
Fusion
  • 1H 1H ? 2H 1e energy
  • 1H 2H ? 3He energy
  • 3He 3He ? 4He 21H energy
  • Reaction that occurs in the sun
  • Temperature 107 K
  • Heavier elements are synthesized in hotter stars
    108 K using Carbon as fuel

62
Nuclear Fusion
  • Fusion would be a superior method of generating
    power.
  • The good news is that the products of the
    reaction are not radioactive.
  • The bad news is that in order to achieve fusion,
    the material must be in the plasma state at
    several million kelvins.

63
Nuclear Fusion(thermonuclear reactions)
  • Tokamak apparati like the one shown at the right
    show promise for carrying out these reactions.
  • They use magnetic fields to heat the material.
  • 3 million K degrees were reached inside but is
    not enough to begin fusion which requires 40
    million K

64
Rates of radioactive decayrate k NN is the
number of radioactive nuclei
  • Activity rate at which a sample decays.
    Expressed in disintegrations per unit time.
  • Becquerel (Bq) SI unit one nuclear
    disintegration per second.
  • Curie (Ci) 3.7x1010 disintegrations per second,
    the rate of decay of 1g of Ra

65
RADIOACTIVE DECAY
  • As a radioactive sample decays, the amount of
    radiation emanating for the sample decays as
    well.
  • After one half life, half of the emanations!

66
Half-Life
  • Half-life is defined as the time required for
    one-half of a reactant to react.
  • Because A at t1/2 is one-half of the original
    A,
  • At 0.5 A0.

67
RADIOACTIVE DECAY
  • Is a first order process. Its rate is
    proportional to the number of radioactive nuclei
    N in the sample rate k N

Time elapsed t k is the decay constant N0 is
the original amount Nt is the amount of sample
at time t
0.693 kt1/2
68
Half life
  • The half life of a reaction is useful to describe
    how fast it occurs.
  • For a first order reaction (like nuclear decay!)
    it does not depend on the initial concentration
    of the reactants.
  • HALF LIFE IS CONSTANT FOR A FIRST ORDER REACTION

69
Half LifeDecay of 10.0 g sample of Sr-90t1/2
28.8 y
70
Problem 1
  • The half life of 210Pb 25 y
  • 1) How much left of a sample of 50 mg will
    remain after 100 y?
  • 2) Find number of half lives
  • 3) Find fraction left
  •  

71
  • 1- 6.25 g
  • 2- 4 half lives
  • 3- 1/16

72
Problem 2
  • How many years will take for 50mg of 210Pb to
    decay to 5 mg?
  • Half life of 210Pb 25 y

73
  • 83 years

74
Problem 3
  • 90 of a radioisotope disintegrates in 36 hs.
    What is the half life?
  •  

75
Problem 4
  •  
  • .953 g of Sr-90 remains after 2 y from a 1.000g
    sample.
  • a) find the half life
  • b) how much will remain after 5 y?
  •  

76
  • Half life 28.8 years
  • Amount left (No) 0.89 g

77
Radioactive Dating
  • A rock contains .257 mg of Pb-206 for every mg of
    U-238.
  • T1/2 4.5 x 10 9 y
  • How old is the rock?

78
  • No we will assume that all the Pb-206 that is
    now present will come from the original U, plus
    the U that is still present
  • (check the answer in textbook!)

79
Calculating half life
  • If 87.5 of a sample of I-131 decays in 24
    days, what is the half life of the
  • I-131?
Write a Comment
User Comments (0)
About PowerShow.com