Radioactivity and decay processes and its types details
ArslanAhmadSaGaR
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Sep 20, 2024
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About This Presentation
Details abot radioactivity process
Slide Content
© Boardworks Ltd 2003
KS4
Radioactive decay and
Model of the atom
KS4
Radioactive decay and
Model of the atom
© Boardworks Ltd 2003
Radioactive waste
Radioactive waste from nuclear power stations is an
environmental concern. The problem is the waste
stays radioactive for thousands of years.
The current solutions are:
1. Store it at the nuclear power station until is filled up.
2. Dump it far out at sea.
3. Store it deep underground in non-permeable rock.
Radioactive waste
Radioactive waste from nuclear power stations is an
environmental concern. The problem is the waste
stays radioactive for thousands of years.
The current solutions are:
1. Store it at the nuclear power station until is filled up.
2. Dump it far out at sea.
3. Store it deep underground in non-permeable rock.
© Boardworks Ltd 2003
Radiation questions
1.What are the three types of radiation?
2.Which type of radiation is the most penetrating?
3.Why is radioactive waste not stored in permeable rock?
4.Why should nuclear power stations not be situated in
geologically active regions?
Alpha, beta and gamma
Gamma
It could contaminate water that seeps through the rock.
Earthquakes could cause radioactive spills.
Radiation questions
1.What are the three types of radiation?
2.Which type of radiation is the most penetrating?
3.Why is radioactive waste not stored in permeable rock?
4.Why should nuclear power stations not be situated in
geologically active regions?
Alpha, beta and gamma
Gamma
It could contaminate water that seeps through the rock.
Earthquakes could cause radioactive spills.
© Boardworks Ltd 2003
What we used to think…
It was believed that atoms were:
1.Spheres of positive charge.
2.With negative charges spread
through it.
This resembled a plum-pudding, so
it was called the ‘Plum –pudding’
model.
This was wrong!
How did we discover current ideas
about the structure of the atom?
What we used to think…
It was believed that atoms were:
1.Spheres of positive charge.
2.With negative charges spread
through it.
This resembled a plum-pudding, so
it was called the ‘Plum –pudding’
model.
This was wrong!
How did we discover current ideas
about the structure of the atom?
© Boardworks Ltd 2003
Rutherford’s team:
Ernest Rutherford and his team of scientists performed a
famous experiment in Manchester:
They fired some alpha particles at a piece of thin gold foil
(only a few atoms thick):
If the ‘Plum Pudding’
model of the atom was
correct, the alpha
particles should pass
straight through and only
be slightly deflected.
This did not
happen.
Rutherford’s team:
Ernest Rutherford and his team of scientists performed a
famous experiment in Manchester:
They fired some alpha particles at a piece of thin gold foil
(only a few atoms thick):
If the ‘Plum Pudding’
model of the atom was
correct, the alpha
particles should pass
straight through and only
be slightly deflected.
This did not
happen.
© Boardworks Ltd 2003
What Rutherford’s team observed……..
1.Most of the alpha particles went straight through
the foil.
2.Some alpha particles were deflected through large
angles.
3. A very few alpha particles were reflected straight
back.
What Rutherford’s team observed……..
1.Most of the alpha particles went straight through
the foil.
2.Some alpha particles were deflected through large
angles.
3. A very few alpha particles were reflected straight
back.
© Boardworks Ltd 2003
Rutherford’s conclusions
Observation Conclusion
Most alpha particles went
straight through the foil.
A few were deflected
through large angles.
A very few were reflected
straight back.
Atoms are mostly space.
The nucleus is very small
compared to the size of
the atom and it contains
most of the mass and all
the positive charge.
Rutherford’s conclusions
Observation Conclusion
Most alpha particles went
straight through the foil.
A few were deflected
through large angles.
A very few were reflected
straight back.
Atoms are mostly space.
The nucleus is very small
compared to the size of
the atom and it contains
most of the mass and all
the positive charge.
© Boardworks Ltd 2003
Task
Pretend you are Ernest Rutherford and you have just
completed your investigation.
Write a letter to a fellow scientist describing your
observations and findings. Include the impact you think
it will have on current thinking.
Dear Dr. Banner,
I am just writing to……
Task
Pretend you are Ernest Rutherford and you have just
completed your investigation.
Write a letter to a fellow scientist describing your
observations and findings. Include the impact you think
it will have on current thinking.
Dear Dr. Banner,
I am just writing to……
© Boardworks Ltd 2003
Label the helium atom and fill in the table:
P_____
N_____
E_____
{
N_____
Particle Mass Charge
Proton
Neutron
Electron
eutron
lectron
roton
ucleus
1
1
1/1840th
+1
none
-1
Label the helium atom and fill in the table:
P_____
N_____
E_____
{
N_____
Particle Mass Charge
Proton
Neutron
Electron
eutron
lectron
roton
ucleus
1
1
1/1840th
+1
none
-1
© Boardworks Ltd 2003
Notation
Atomic number:
The number of
protons (which is the
same as number of
electrons) in a neutral
atom.
Mass number:
The number of
protons plus the
number of neutrons in
a neutral atom.
Element
symbol
A
X
N
Notation
Atomic number:
The number of
protons (which is the
same as number of
electrons) in a neutral
atom.
Mass number:
The number of
protons plus the
number of neutrons in
a neutral atom.
Element
symbol
A
X
N
© Boardworks Ltd 2003
Name the elements shown and calculate the numbers
of protons, neutrons and electrons for the elements:
12
C
6
75
As
33
127
I
53
Name the elements shown and calculate the numbers
of protons, neutrons and electrons for the elements:
12
C
6
75
As
33
127
I
53
© Boardworks Ltd 2003
Use a periodic table to fill in the table below:
Element Protons NeutronsElectrons
H
He
Li
Be
B
C
N
O
F
Ne
Na
Mg
Al
Si
Use a periodic table to fill in the table below:
Element Protons NeutronsElectrons
H
He
Li
Be
B
C
N
O
F
Ne
Na
Mg
Al
Si
© Boardworks Ltd 2003
Calculate the number of protons, electrons and
neutrons shown below -
12
C
6
13
C
6
14
C
6
These are all the element carbon, what is the difference between them?They have different numbers of neutrons.What do we call atoms of the same element with different numbers of
neutrons?Isotopes
What do we call isotopes that are unstable and emit radiation to become more
stable?Radioisotopes
Calculate the number of protons, electrons and
neutrons shown below -
12
C
6
13
C
6
14
C
6
These are all the element carbon, what is the difference between them?They have different numbers of neutrons.What do we call atoms of the same element with different numbers of
neutrons?Isotopes
What do we call isotopes that are unstable and emit radiation to become more
stable?Radioisotopes
© Boardworks Ltd 2003
Radioactive Decay
Why is it that there are different types of radiation?
What is going on inside the nucleus?
The three types of decay are………
Alpha
Beta
Gamma
Radioactive Decay
Why is it that there are different types of radiation?
What is going on inside the nucleus?
The three types of decay are………
Alpha
Beta
Gamma
© Boardworks Ltd 2003
Alpha decayType of decay:
What is emitted?
Description of decay:
Example of decay:
Effect on A and Z:
Alpha particle (helium nuclei)
238
234 4
U Th + + energy
92 90 2
2 neutrons and 2 protons are
emitted from the nucleus.
A decreases by 4, Z decreases by 2
(A-4, Z-2)
Alpha decayType of decay:
What is emitted?
Description of decay:
Example of decay:
Effect on A and Z:
Alpha particle (helium nuclei)
238
234 4
U Th + + energy
92 90 2
2 neutrons and 2 protons are
emitted from the nucleus.
A decreases by 4, Z decreases by 2
(A-4, Z-2)
© Boardworks Ltd 2003
Beta decay
Type of decay:
What is emitted?
Description of decay:
Example of decay:
Effect on A and Z:
High energy electron
14
14 0
C N + + energy
6 7 -1
A neutron in the nucleus decays
into a proton and a high energy
electron which is emitted.
A stays the same, Z increases by 1
(A=, Z+1)
Beta decay
Type of decay:
What is emitted?
Description of decay:
Example of decay:
Effect on A and Z:
High energy electron
14
14 0
C N + + energy
6 7 -1
A neutron in the nucleus decays
into a proton and a high energy
electron which is emitted.
A stays the same, Z increases by 1
(A=, Z+1)
© Boardworks Ltd 2003
Gamma decay
Type of decay:
What is emitted?
Description of decay:
Effect on A and Z:
High energy electromagnetic radiation.
Nucleus changes shape into a
more stable shape. Gamma
radiation emitted as a result.
A stays the same, Z stays the same
(A=, Z=)
Gamma decay
Type of decay:
What is emitted?
Description of decay:
Effect on A and Z:
High energy electromagnetic radiation.
Nucleus changes shape into a
more stable shape. Gamma
radiation emitted as a result.
A stays the same, Z stays the same
(A=, Z=)
© Boardworks Ltd 2003
Half life
The time it takes the number of radioactive
nuclei in a sample to decrease by 50%.
The time it takes the count rate from a
radioisotope to decrease by 50%.
There are two definitions of half life:
You must learn both of these definitions!
Half life
The time it takes the number of radioactive
nuclei in a sample to decrease by 50%.
The time it takes the count rate from a
radioisotope to decrease by 50%.
There are two definitions of half life:
You must learn both of these definitions!
© Boardworks Ltd 2003
Graphical representation of half life
Decay rate
(counts/min)
Time (min)
80
60
40
20
2 4 6 8
What is the half life of the radioisotope
represented by the following graph?
The time it takes the count rate to
decrease from 80 per min to 40 per min is
what?
2 mins
Double check, the time it takes
the count rate to decrease from
40 per min to 20 per min is?
2 mins
The half life of the radioisotope is 2 mins.
Graphical representation of half life
Decay rate
(counts/min)
Time (min)
80
60
40
20
2 4 6 8
What is the half life of the radioisotope
represented by the following graph?
The time it takes the count rate to
decrease from 80 per min to 40 per min is
what?
2 mins
Double check, the time it takes
the count rate to decrease from
40 per min to 20 per min is?
2 mins
The half life of the radioisotope is 2 mins.
© Boardworks Ltd 2003
Half life questions
1.What are the two definitions of half life?
2.If 1/64
th
of an original radioisotope is left after 1
hour, what is the half life of the sample?
3.A radioisotope has a half life of 12 minutes. What
fraction of the radioisotope will be left after 2
hours?
4.The background radiation in a laboratory is 13
counts per minute. The count rate from a
radioisotope is measured and it has a reading of
119 counts per minute. If the half life of the
radioisotope is 10 minutes, what will be the reading
20 minutes later?
Half life questions
1.What are the two definitions of half life?
2.If 1/64
th
of an original radioisotope is left after 1
hour, what is the half life of the sample?
3.A radioisotope has a half life of 12 minutes. What
fraction of the radioisotope will be left after 2
hours?
4.The background radiation in a laboratory is 13
counts per minute. The count rate from a
radioisotope is measured and it has a reading of
119 counts per minute. If the half life of the
radioisotope is 10 minutes, what will be the reading
20 minutes later?
© Boardworks Ltd 2003
Carbon Dating
All living things take in a little radioactive carbon-14
in photosynthesis, as well as the normal carbon-12.
When living things die, they stop taking in carbon-14
and so the carbon-14 present at death slowly
decays to carbon-12 (half-life is 5 600 years).
The radioactivity due to the decay of carbon-14 can
be used to date bones, wood, paper and cloth.
Carbon Dating
All living things take in a little radioactive carbon-14
in photosynthesis, as well as the normal carbon-12.
When living things die, they stop taking in carbon-14
and so the carbon-14 present at death slowly
decays to carbon-12 (half-life is 5 600 years).
The radioactivity due to the decay of carbon-14 can
be used to date bones, wood, paper and cloth.
© Boardworks Ltd 2003
Example
A fresh bone gives a radioactive count of 170 counts
per minute. Another ancient bone of the same mass
gives a count rate of 50 counts per minute. The
background count is 10 counts per minute.
How old is the bone?
Counts due to bones are 170 - 10 = 160 (fresh) and
50 - 10 =40 (ancient)
The count rate of the carbon-14 has fallen to one quarter of
its original value, i.e. 160/2 = 80, 80/2=40.
This is two half lives,
So the bone is 5600 x 2 =11200 years old.
click
Example
A fresh bone gives a radioactive count of 170 counts
per minute. Another ancient bone of the same mass
gives a count rate of 50 counts per minute. The
background count is 10 counts per minute.
How old is the bone?
Counts due to bones are 170 - 10 = 160 (fresh) and
50 - 10 =40 (ancient)
The count rate of the carbon-14 has fallen to one quarter of
its original value, i.e. 160/2 = 80, 80/2=40.
This is two half lives,
So the bone is 5600 x 2 =11200 years old.
click
© Boardworks Ltd 2003
Nuclear Power
When a nucleus decays it gives out heat energy.
In a nuclear power station, the uranium-235 atoms decay
and give out energy and neutrons.
Each time a uranium atom splits it produces 2 or 3
neutrons (depending on the reaction). These go on to hit
other uranium atoms, which causes them to decay. A
chain reaction is set up where more and more energy is
released. In a nuclear reactor the process is carefully
controlled so that neutrons are absorbed harmlessly and
the energy released is controlled.
In a nuclear bomb the reaction is not controlled, and the
bomb explodes!
Nuclear Power
When a nucleus decays it gives out heat energy.
In a nuclear power station, the uranium-235 atoms decay
and give out energy and neutrons.
Each time a uranium atom splits it produces 2 or 3
neutrons (depending on the reaction). These go on to hit
other uranium atoms, which causes them to decay. A
chain reaction is set up where more and more energy is
released. In a nuclear reactor the process is carefully
controlled so that neutrons are absorbed harmlessly and
the energy released is controlled.
In a nuclear bomb the reaction is not controlled, and the
bomb explodes!
© Boardworks Ltd 2003
Nuclear Power - fission
Fast neutron from previous decay cause the Uranium nucleus to split.
Nuclear Power - fission
Fast neutron from previous decay cause the Uranium nucleus to split.
© Boardworks Ltd 2003
Nuclear Power
Kr
Ba
n
n
n
n
F
is
s
io
n
Uranium
In the reaction above a
neutron from a previous
decay can lead to more
and more decays.
This is called a chain reaction.
More
decays
Nuclear Power
Kr
Ba
n
n
n
n
F
is
s
io
n
Uranium
In the reaction above a
neutron from a previous
decay can lead to more
and more decays.
This is called a chain reaction.
More
decays
© Boardworks Ltd 2003
During alpha decay, which of the following is true?
A.Relative atomic mass increases by 2
B.Relative atomic mass decreases by 2
C.Relative atomic mass increases by 4
D.Relative atomic mass decreases by 4
During alpha decay, which of the following is true?
A.Relative atomic mass increases by 2
B.Relative atomic mass decreases by 2
C.Relative atomic mass increases by 4
D.Relative atomic mass decreases by 4
© Boardworks Ltd 2003
During beta decay, which of the following is true?
A.Atomic number increases by 1
B.Atomic number decreases by 1
C.Atomic number increases by 2
D.Atomic number decreases by 2
During beta decay, which of the following is true?
A.Atomic number increases by 1
B.Atomic number decreases by 1
C.Atomic number increases by 2
D.Atomic number decreases by 2
© Boardworks Ltd 2003
What fraction of a radioactive sample is left after
4 half lives?
A.1/2
B.1/4
C.1/8
D.1/16
What fraction of a radioactive sample is left after
4 half lives?
A.1/2
B.1/4
C.1/8
D.1/16
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