Title: Nuclear Chemistry a.k.a. Radiation AAAAHHHHH NOOOOO! Duck and cover!
1Nuclear Chemistrya.k.a. RadiationAAAAHHHHH
NOOOOO!Duck and cover!
2What do you know?
- All nuclear materials remain highly toxic for
thousands of years. - false -Some radioisotopes have-lives of seconds
or days, while others like plutonium-239 has a
half-life of 2.4 x 104 years.
3What do you know?
- Man-made radiation is more toxic to humans than
naturally occurring radiation even if the dose is
the same. - false - The body makes no distinction it sees
radiation as deposited energy regardless of its
source.
4What do you know?
- The human body has the capability to repair
damaged caused by exposure to radiation. - true - Many of the DNA lesions induced by
ionizing radiation are similar to identical to
those induced as a consequence of normal
metabolic activity. DNA repair mechanisms can act
to reduce the consequences of this damage.
5What do you know?
- In the US, most cases of cancer in humans are
known to be caused by man-made radiation. - false - Most cancers have an unknown cause or
etiology.
6What do you know?
- I would rather live within a 50 mile radius of a
coal-burning plant than a nuclear power plant. - false - Actually a coal burning plant gives off
slightly more radioactivity due to the thorium
and uranium content in coal. But in both cases
the levels are extremely low.
7What do you know?
- One of the chief dangers from nuclear power
plants is that they can explode like a nuclear
bomb.
8- false - There's a big difference between a
nuclear core and a nuclear bomb. After
detonation, the density of uranium (or plutonium)
atoms in a bomb is incredibly high, enough for
fissions to take place and energy to be released
in a hundred millionth of a second! So it flies
apart. The density of atoms in a nuclear core is
much less, and, even in a meltdown situation
would generate heat at a much slower rate than is
necessary to fly apart. The act of meltdown
actually terminates the explosive process,
because when a core "melts down" it spreads out
and goes sub-critical.
9What do you know?
- It is safer to drive behind a tanker truck
carrying gasoline than a truck load of spent
nuclear fuel. - false - People occasionally die in gasoline truck
accidents, but the DOE and the nuclear industry
claim that no one has died or been hurt by a
radiation release due to a nuclear waste
transportation accident.
10What do you know?
- On average, people are exposed to more radiation
from nuclear power plants than from radon gas in
homes. - false - An individual gets about 200 millirems of
radiation per year from naturally occurring
radon. A normally functioning nuclear power plant
exposes a person to about.01 millirem, if the
person lives within 50 miles of the plant.
11What do you know?
- Since the construction of the first nuclear power
plant, man-made radiation in known to have
resulted in new species of plants and animals. - false - New species don't occur any more
frequently today than before nuclear plants were
built.
12What do you know?
- The fact that nuclear power plants have elaborate
evacuation plans for the surrounding area
indicates they are inherently more dangerous than
other types of plants.
13What do you know?
- false - Evacuation plans have only been around
since 1980 and are an example of "regulatory
ratcheting" by the Nuclear Regulatory Commission.
Other countries do not have these plans. Chemical
plants do not have evacuation plans even though
evacuations in their vicinity are more likely to
be necessary than around a nuclear power plant.
Most evacuations are due to rail or truck
accidents involving toxic chemicals.
14The 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.
15Isotopes
- 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
16Radioactivity
- 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.
17Types of Radioactive Decay Alpha Decay
- Loss of an ?-particle (a helium nucleus)
18Types of Radioactive Decay Beta Decay
- Loss of a ?-particle (a high energy electron)
19Types of Radioactive Decay Positron Emission
- Loss of a positron (a particle that has the same
mass as but opposite charge than an electron)
20Types of Radioactive Decay Gamma Emission
- Loss of a ?-ray (high-energy radiation that
almost always accompanies the loss of a nuclear
particle)
21Page 4
- Homework Read Page 5 and answer page 6 in packet.
22Stable Nuclei
- There are no stable nuclei with an atomic number
greater than 83. - These nuclei tend to decay by alpha emission.
23Radioactive 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).
24Nuclear Fission
- How does one tap all that energy?
- Nuclear fission is the type of reaction carried
out in nuclear reactors.
25Nuclear 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. - This process continues in what we call a nuclear
chain reaction.
26Nuclear Fission
- If there are not enough radioactive nuclides in
the path of the ejected neutrons, the chain
reaction will die out. - Therefore, there must be a certain minimum amount
of fissionable material present for the chain
reaction to be sustained Critical Mass.
27Nuclear Reactors
- In nuclear reactors the heat generated by the
reaction is used to produce steam that turns a
turbine connected to a generator.
28Nuclear 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.
29Nuclear 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. - Tokamak apparati like the one shown at the right
show promise for carrying out these reactions. - They use magnetic fields to heat the material.
30Nuclear Transformations
- Nuclear transformations can be induced by
accelerating a particle and colliding it with the
nuclide.
These particle accelerators are enormous, having
circular tracks with radii that are miles long.
31Page 8 Page 10
32Nuclear Equations
- Just like a math equation.
- Both sides must equal.
33Half Life(no,not middle age)
- Read Page 17
- The half-life of a radioactive nuclide is the
amount of time it takes for half of that nuclide
to decay into a stable nuclide.
34The half-life of Carbon-14 is 5730 years
- After 5730 years, ½ the mass of an original
sample of Carbon-14 remains unchanged. - After another 5730 years, ¼ (half of the half) of
an original sample of Carbon-14 remains
unchanged. - The half-life of a radioactive nuclide cannot be
changed.
35Regents Question
As a sample of the radioactive isotope 131I
decays, its half-life (1) decreases (2)
increases (3) remains the same
þ
36How to determine how much of a radioactive
isotopes remains unchanged after a period of
time.
- Determine how many half-lives have gone by
(Time/half-life) - Halve the mass of the starting material for each
half-life period that goes by. - How much of a 20.g sample of 131I remains
unchanged after 24 days? - The half-life period is 8 days so 24 days is 3
half-lives. Half the mass three times. - 20.g 10.g 5.0g
2.5g
8 days
8 days
8 days
37Regents Question
- Exactly how much time must elapse before 16 grams
of potassium-42 decays, leaving 2 grams of the
original isotope? - 8 x 12.4 hours
- (2) 2 x 12.4 hours
- (3) 3 x 12.4 hours
- (4) 4 x 12.4 hours
16 ? 8 ? 4 ? 2
þ
38Page18 . . .
39Benefits of Radioactive isotopes
- Tracers are used to follow the course of
chemical (organic) or biological reactions - (C-14)
- Medical isotopes (radioactive), with short
half-lives are quickly eliminated from body - Technetium-99 pinpoints brain tumors
- Iodine-131 diagnosis and treatment of thyroid
disorders - Radium and Cobalt-60 treatment of cancer
40Benefits of Radioactive isotopes
- Food can be stored longer because radiation kills
bacteria, yeast and molds - Radioactive dating
- Geologic dating is based on half-life.
Uranium-238 occurs naturally in rock, it decays
to lead-206. - Dating living materials (organisms that were
previously alive). The ratio of C-14 to C-12 can
determine the age of a sample of wood, bone,
animal skin, or fabric.
41Benefits of Radioactive isotopes
- Nuclear Power produce electricity
- Industrial Measurement a beam of subatomic
particles (alpha, beta or gamma) is blocked by a
metal of a certain thickness. Measuring the
fraction of the beam that is blocked determines
the thickness of the metal.
42Risks of Radioactive isotopes
- Biological Damage exposure to radiation can
damage cells, or an organism. When sex cells
are damaged, offspring may be affected. - Long term storage it is not known if storing
radioactive isotopes is safe. - Accidents cause fuel to escape nuclear reactors
(earthquake in Japan).