Chapter 31 - Nuclear Physics and Radioactivity PDF

Summary

These lecture notes cover nuclear physics and radioactivity. Topics include different types of decay, half-life, radioactive dating, and the four fundamental forces: gravity, electromagnetism, strong force, and weak force. The notes also explain the properties of select particles, isotopes, nuclear density, and the concepts of binding energy and mass-energy equivalence.

Full Transcript

Physics
Cutnell & Johnson

Chapter 31
Nuclear Physics and Radioactivity
Copyright ©2022 John Wiley & Sons, Inc.
EdPuzzle Introduction
Do the video Quiz to learn about different types of decay

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EdPuzzle Introduction
Do the video Quiz to learn about half-life and
radioactive dating

Copyright ©2022 John Wiley & Sons, Inc. 3
As far as we know, everything in that has ever happened in
the universe is due to 4 forces.
If you find a 5th force you can win a Nobel prize…
Copyright ©2022 John Wiley & Sons, Inc. 4
1. Gravity we experience every day and allows all
objects with mass to attract one another
2. Electromagnetism is responsible for all Chemistry,
electricity, magnetism, light and contact forces
(essentially everything we did FSKS in 123…)
Copyright ©2022 John Wiley & Sons, Inc. 5
We will introduce the other two forces today:
3. Strong Force: Binds Protons and Neutrons in nucleus
(Binds all particles made of quarks)
– Very short range! Don’t notice in everyday life
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We will introduce the other two forces today:
4. Weak Force: Causes radioactive decay, decay
(Transforms neutrons into protrons & vice versa!)
– Very short range also! Don’t notice in everyday life
Copyright ©2022 John Wiley & Sons, Inc. 7
31.1 Nuclear Structure (1 of 6)
All matter around us, is made of atoms.
Atoms have electrons outside, and a nucleus inside
The atomic nucleus consists of positively charged protons
and neutral neutrons.

Proton’s and Neutrons are made of quarks
(don’t need to know)
Copyright ©2022 John Wiley & Sons, Inc. 8
31.1 Nuclear Structure (2 of 6)
Table 31.1 Properties of Select Particles

Mass Mass
Particle Electric Charge (C) Kilograms (kg) Atomic Mass Units (u)
Electron negative 1.60 times 10 to the power negative 19 9.109382 times 10 to the power negative 31 5.485799 times 10 to the power negative 14

 1.60 10  19 9.109 382 10  31 5.485 799 10  14
Proton positive 1.60 times 10 to the power negative 19 1.672622 times 10 to the power negative 27
1.007 276
1.60 10  19 1.672 622 10  27

Neutron 0 1.674927 times 10 to the power negative 27
1.008 665
1.674 927 10  27

Hydrogen atom 0 1.673534 times 10 to the power negative 27
1.007 825
1.673 534 10  27

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31.1 Nuclear Structure (3 of 6)

Atomic number = Type of element
-Number of protons = number of electrons
-Number of electrons = Chemical properties
- Chemical properties = Type of element
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31.1 Nuclear Structure (4 of 6)
Nuclei that contain the same number of protons but a
different number of neutrons are known as isotopes.

Same Atomic number (protons) = Type of element Chemical properties

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31.1 Nuclear Structure (3 of 6)
Test your knowledge with this game!

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31.1 Nuclear Structure (5 of 6)
Nuclei aren’t 100% spherical,
their radius is instead given by
1
r 1.2 10  15 m  A 3

`

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 Conceptual Example 1 Nuclear Density
It is well known that lead and oxygen contain different atoms and
that the density of solid lead is much greater than gaseous oxygen.
Using the equation, decide whether the density of the nucleus in a
lead atom is greater than, approximately equal to, or less than that in
an oxygen atom.

𝑟 ≈ ( 1.2 × 10− 15 𝑚 ) 𝐴

1 1

𝑟 𝑃𝑏 ≈ ( 1.2 × 10
≈ ( 1.2 × 10− 15 𝑚 ) (15.999) 3 − 15
𝑚 ) (207.2) 3

− 15
3. 02 × 10 𝑟 𝑚≈ 7.1 × 10 𝑚
− 15
𝑃𝑏

Lead (Pb) nuclei has a radius which is more
than double that of Oxygen (O)
Copyright ©2022 John Wiley & Sons, Inc. 14
31.2 The Strong Nuclear Force and the
Stability of the Nucleus (1 of 2) Strong Nuclear force

The mutual electromagnetic repulsion
(Coulomb Force) of the protons tends
to push the nucleus apart.

What then, holds the nucleus together?
Strong Nuclear Force:
Very strong! Binds Protons and Neutrons in nucleus
(Binds all particles made of quarks)
– Very short range! Don’t notice in everyday life
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 Strong Nuclear force

Strong Nuclear force 137 times stronger
than Electromagnetic repulsion
ONLY at VERY Short distances
Electromagnetic force works at large scales
If nucleus too big, electromagnetic force dominates
This makes nucleus unstable!
Particle decays!
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 Strong Nuclear force

etic
n
ag
o m
tr
l ec e
E rc
fo Strong Nuclear force

etic
a gn
m
ctro
e
El rce
fo

During nuclear decay, the nucleus will split into smaller pieces
Since the nucleus is smaller, there will be a balance of forces and
nucleus will be more stable.
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31.2 The Strong Nuclear Force and the
Stability of the Nucleus (2 of 2)
As for stability.
The neutrons act like glue
Add additional Strong Force ,
No extra repulsive
electromagnetic force.

Strong Nuclear force

Copyright ©2022 John Wiley & Sons, Inc. 18
 Example: Where’d all the mass go?
Uranium-238 undergoes alpha decay to form Thorium-234 by emitting
an alpha particle (which consists of 2 protons and 2 neutrons). The
mass of Uranium-238 is 238.0508 atomic mass units (u), the mass of
Thorium-234 is 234.0436 u, and the mass of the alpha particle is
4.0026 u.
(a) Calculate the mass before and after of this nuclear reaction.
𝑚𝑖 =𝑚𝑈 =238.0508 𝑢
𝑚 𝑓 =𝑚 𝑇h + 𝑚𝐻𝑒
¿ 234.0436 𝑢+4.0026 𝑢
¿238.0462 𝑢
𝑚 𝑓 ≠ 𝑚𝑖 …
Δ 𝑚=𝑚 𝑓 − 𝑚𝑖 ¿ −0.0046 𝑢
Where did the mass go? Is mass not conserved in nature?!
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 2
𝐸=𝑚 𝑐
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 2
2
𝐸=𝑚 𝑐
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 Einstein and
1905, Einstein showed that mass (m) can
be converted into pure energy (E)!

Since m/s, a little bit of mass can turn
into a LOT of energy
This happens when big nuclei split by
radioactive decay (Nuclear fission)
Ex. Nuclear power + Atomic bombs!
This happens when small nuclei fuse,
like 2 hydrogens making helium
(Nuclear fusion)
Ex. THE POWER OF THE SUN!
Copyright ©2022 John Wiley & Sons, Inc. 22
Sunshine and starlight is
Hydrogen fuses into helium in the core of the sun (and all stars)
Helium has LESS mass than hydrogen it is made of
Missing mass = SUNLIGHT (and STARLIGHT!)

Copyright ©2022 John Wiley & Sons, Inc. 23
 Example: Where’d all the mass go?
Uranium-238 undergoes alpha decay to form Thorium-234 by emitting
an alpha particle (which consists of 2 protons and 2 neutrons). The
mass of Uranium-238 is 238.0508 atomic mass units (u), the mass of
Thorium-234 is 234.0436 u, and the mass of the alpha particle is
4.0026 u.
(a) Calculate the mass before and after of this nuclear reaction.
𝑚𝑖 =𝑚𝑈 =238.0508 𝑢
𝑚 𝑓 =𝑚 𝑇h + 𝑚𝐻𝑒
¿ 234.0436 𝑢+4.0026 𝑢
¿238.0462 𝑢
𝑚 𝑓 ≠ 𝑚𝑖 …
Δ 𝑚=𝑚 𝑓 − 𝑚𝑖 ¿ −0.0046 𝑢
Where did the mass go? Is mass not conserved in nature?!
Copyright ©2022 John Wiley & Sons, Inc. 24
 Example: Where’d all the mass go?
Uranium-238 undergoes alpha decay to form Thorium-234 by emitting
an alpha particle (which consists of 2 protons and 2 neutrons). The
mass of Uranium-238 is 238.0508 atomic mass units (u), the mass of
Thorium-234 is 234.0436 u, and the mass of the alpha particle is
4.0026 u.
(a) Calculate the mass before and after of this nuclear reaction.
What is the energy released in this alpha decay process, in MeV?
Note: 1 u = 931.5 MeV ( when using mass in u )
𝑚=0.0046 𝑢 Binding energy = Energy released
𝐸=𝐵𝑖𝑛𝑑𝑖𝑛𝑔 𝑒𝑛𝑒𝑟𝑔𝑦
¿
E = ((ΔΔ
𝑚) 𝑐 ¿ (2
𝑚0.0046 ) )𝑢(931.5 MeV ≈4.29 𝑀𝑒𝑉 )

Copyright ©2022 John Wiley & Sons, Inc. 25
31.3 The Mass Deficit of the Nucleus
and Nuclear Binding Energy (1 of 4)
This energy released is called Binding energy
We need to put energy in to break nuclear bonds!
If the bonds are made, this energy is released
Similar to sound energy released from potential energy
when a ball hits the floor

Binding energy Mass deficit c 2 m c 2
Copyright ©2022 John Wiley & Sons, Inc. 26
 Example 3: The Binding Energy of the Helium Nucleus Revisited
The atomic mass of helium is 4.0026u and the atomic mass of hydrogen is
1.0078 u and neutrons have mass 1.0087 u. Using atomic mass units,
instead of kilograms, obtain the binding energy of the helium nucleus.
Note: 1 u = 931.5 MeV ( when using mass in u )
𝑖𝑛𝑑𝑖𝑛𝑔 ¿ 𝑒𝑛𝑒𝑟𝑔𝑦 =¿ ¿
¿ ( 0.0304 𝑢 ) (931.5 MeV )
m𝑖 =𝑚 𝐻𝑒=4.0026 𝑢 ¿ 28. 32 MeV
m 𝑓 =2 𝑚 𝐻 +2 𝑚𝑛= 2( 1.0078𝑢¿+2(1.008 7𝑢¿ u
Δ 𝑚=𝑚 𝑓 − 𝑚𝑖
¿ 4.03 3 u − 4.0026 ¿ 0.0304
𝑢 u

Copyright ©2022 John Wiley & Sons, Inc. 27
31.3 The Mass Deficit of the Nucleus and
Nuclear Binding Energy (4 of 4)
heavy elements
undergo fission

Nuclear fission

Nuclear fusion

Light elements
undergo fusion

Copyright ©2022 John Wiley & Sons, Inc. 28
The elements from the periodic table (and
in you) are created in stars…
Supernovae explosions!
Nuclear fusion

All elements heavier
than iron Fe are
created when stars
die… Supernovae
explosions!

All elements from He to iron Fe are created by
nuclear fusion in stars!

Copyright ©2022 John Wiley & Sons, Inc. 29
The elements from the periodic table (and
in you) are created in stars…

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 31.4 Radioactivity (1 of 6)

The three types of particles emitted by
radioactive nuclei have different piercing power
NEED TO UNDERSTAND FOR EXAM
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31.4 Radioactivity (1 of 6)

Positive charge

Neutral (Zero charge)

Negative charge

A magnetic field separates the three types of particles
emitted by radioactive nuclei.
Copyright ©2022 John Wiley & Sons, Inc. 32
31.4 Radioactivity (2 of 6)
α Decay
When an unstable nucleus emits two protons and two neutrons

A
Z
P A 4
Z 2
D  2
2
He
Copyright ©2022 John Wiley & Sons, Inc. 33
 31.4 Radioactivity (3 of 6)
particles smoke detector
Smoke detectors contain a small radioactive source
This constantly emits particles
particles hits electrons out of molecules in air
This creates a constant current.
When smoke blocks the path of particles, no current is created
ALARM IS TRIGGERED!

Copyright ©2022 John Wiley & Sons, Inc. 34
31.4 Radioactivity (4 of 6)
β Decay
When an unstable nucleus: 1. Emits an electron
2. Neutron becomes a proton

A
Z
P A
Z 1
D  0
1
e
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31.4 Radioactivity (5 of 6)
γ Decay
When an unstable nucleus emits a
(high energy electromagnetic wave)

Element, mass and atomic number stay constant
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31.4 Radioactivity (5 of 6)
γ Decay
Gamma rays are ionizing radiation, which can cause
mutations in DNA (why Chernobyl is dangerous…)

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31.4 Radioactivity (6 of 6)

Gamma knife
Radioactive materials provides gamma rays targeted at
tumors in the brain, brain surgery without a knife!
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Radioactive materials can be injected into patients to detect
cancerous tumors
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31.9 Radiation Detectors (1 of 2)
Radioactivity is measured with devices that convert the
radiation into currents, creating a signal

A Geiger counter A scintillation counter
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Example: Identifying decay products

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Example: Identifying decay products
What products would be formed if could undergo:
Use conservation of charge and atomic mass number!
a)
22
2284−4 4
9
942
−2 𝑃𝑢+
𝑈 2 𝐻𝑒
b)
228 0
95 𝐴𝑚 +¿ −1 𝑒 ¿ neutron
becomes
Charge:94
→ 95 +¿ − 1 proton
c)
228
94 𝑃𝑢 +𝛾
Copyright ©2022 John Wiley & Sons, Inc. 42
Example: Identifying decay products
What products would be formed if could undergo:
Use conservation of charge and atomic mass number!
a)
1 83 4
187− 4
73
75− 2 𝑅𝑒+
𝑇𝑎 2 𝐻𝑒
b)
187 0
76 𝑂𝑠 +¿ −1 𝑒 ¿ neutron
becomes
Charge:94
→ 95 +¿ − 1 proton
c)
187
75 𝑅𝑒 +𝛾
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31.8 Radioactive Decay Series (1 of 2)
The sequential decay of one nucleus after another is called
a radioactive decay series.

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Example: Nuclear decay series
A single atom of Thorium-238 undergoes six different
decays
Complete the chain below, writing the element formed
with its atomic mass number and proton number clearly
labeled, Use the periodic table to identify the elements.

2 28 2 28 2 24 2 20 2 20
88 𝑅𝑎 89 𝐴𝑐 87 𝐹𝑟 85 𝐴𝑡 86 𝑅𝑛
- - - - - -
decay deca deca deca deca deca
y y y y y

Copyright ©2022 John Wiley & Sons, Inc. 45
Don’t need to add in decay questions for exam

31.5 The Neutrino
During beta decay, energy is released. However, it is found that
most beta particles do not have enough kinetic energy to
account for all of the energy released.
The additional energy is carried away a neutrino.

N

234
90
Th 234
91
Pa  0
1
e  Neutrino:
Italian for little neutral one
Copyright ©2022 John Wiley & Sons, Inc. 46
 LAST SECTION OF FSKS 123

31.6 Radioactive Decay and Activity (1 of
2)
As particles decay, they decrease. We measure in ½ life.
Half life :
The time it takes for half of the radioactive nuclei to disintegrate

Your energy levels at this
point in the semester
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 LAST SECTION OF FSKS 123

31.6 Radioactive Decay and Activity (1 of
2)
As particles decay, they decrease. We measure in ½ life.
Half life :
The time it takes for half of the radioactive nuclei to disintegrate

This process is governed by two equations
𝑙𝑛 2
𝑁 =𝑁 0 𝑒
− 𝜆𝑡
; 𝜆=
𝑇 1/ 2
Number of Nuclei after time
Number of Nuclei at the start
`
decay constant (related to ½ life)
time passed (AGE OF OBJECT!)
Copyright ©2022 John Wiley & Sons, Inc. 48
31.6 Radioactive Decay and Activity (2 of
2)
Half life can range from less than a second to billions of years.
Different half lives are useful for dating different objects.
Isotope Half-Life
Polonium 214
84
Po
P o left superscript 214 subscript 84 1.64 times 10 to the power negative 4 s

1.64 10  4 s
Krypton K r left superscript 89 subscript 36
89
Kr 3.16 min
36

Radon Rn
R n left superscript 222 subscript 86
222
86
3.83 d
Strontium Sr
S r left superscript 90 subscript 38
90
38
29.1 yr
Radium 226
Ra
R a left superscript 226 subscript 88 1.6 times 10 to the power 3 yr

1.6 10 3 yr
88

Carbon C left superscript 14 subscript 6 Age of dead trees,
5.73 10 3 yr
5.73 times 10 to the power 3 yr
14
C
6
animals, etc.
Uranium 238
U
U left superscript 238 subscript 92 4.47 times 10 to the power 9 yr

4.47 10 9 yr
92 Age of meteors,
Indium 115
In
I n left superscript 115 subscript 49
4.41 times 10 to the power 14 yr

4.411014 yr earth itself!
49

Table 31.2 Some Half-Lives
Copyright for
©2022 John Wiley & Sons,Radioactive
Inc. Decay 49
Conceptual Example 12 Dating a Bottle of Wine
A bottle of red wine is thought to have been sealed about 5 years
ago. The wine contains a number of different atoms, including
carbon, oxygen, and hydrogen. The radioactive isotope of carbon is
the familiar C-14 with half- life of 5730 yr.
The radioactive isotope of oxygen is O-15 with a half life of 122.2 s.
The radioactive isotope of hydrogen is called tritium and has a half
life of 12.33 yr. The activity of each of these isotopes is known at
the time the bottle was sealed. However, only one of the isotopes is
useful for determining the age of the wine. Which is it?

Tritium, as the half life is closer to the expected opening date of wine

O-14 will experienced to many half-lives and will barely be detectable
C-14 will barely have decayed in 5 years, difference not detectable.

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 Make sure you can do this for exam!

31.7 Radioactive Dating (3 of 3)
Living organisms absorb carbon-14 into their tissue. Once they
die, the absorption stops,
C-14 undergoes decay into N-14. The C-14 has a half life of
5730 years
This is used to date fossils and other living objects.

Copyright ©2022 John Wiley & Sons, Inc. 51
Example: Carbon-14 dating
Scientists know that C-14 decays in N-14 when organisms die. C-14 has
a half- life of 5730 years and is used to determine the age of fossils.
(a) Determine the decay constant for carbon-14
(b) Determine the age of a Human skull containing 76.6% of its original
amount of C-14 ()
0.693 0.693
(a) 𝜆=? 𝜆= ¿
𝑇 1/2 5730 𝑦𝑒𝑎𝑟𝑠
KEEP IN UNITS OF HALF-LIFE
−4 −1
Age will then be give in years ¿ 1.21×10 𝑌𝑒𝑎𝑟 𝑠
(b)𝑁 =𝑁 0 𝑒 − 𝜆 𝑡 𝑁 =0.76.6 𝑁 0
− 𝜆𝑡 𝑁 𝑡 =?
𝑒 =
𝑁0
𝑁
− 𝜆 𝑡 =𝑙𝑛
𝑁0
`

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31.7 Radioactive Dating (3 of 3)
When certain igneous rocks are created they contain only
Uranium-238 (U-238)
These rocks decays into lead-206 (Pb-206) with a half life of
4.47 billion years ()
This is used to date meteors and the Earth itself!

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Example: U-238 dating
Scientists know that U-238 decays in Pb-206 when rocks form. U-238
has a half- life of 4.47 billion years
(a) Determine the decay constant for uranium-238
(b) Determine the age of the moon, using a moon rock containing
55.5% of its original amount of U-238 ()
9
(a) 𝑇 1/ 2=4.47×10 𝑦𝑟𝑠
0.693¿ 0.693
𝜆= 9 ¿ 1.55 ×10
−10
𝑦𝑟 𝑠
−1
𝑇 1/2 4.47× 10 𝑦𝑟𝑠
(b)𝑁 =𝑁 0 𝑒
− 𝜆𝑡
𝑁 =0.555 𝑁 0
𝑡 =?
The moon is 3.8 billion
years old
` 9 ❑
≈3.80× 10 𝑦𝑟𝑠
Copyright ©2022 John Wiley & Sons, Inc. 54
31.7 Radioactive Dating (3 of 3)
See if you can calculate age of all objects in game below.
(Takes long to load, but this will help for exam…)

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THE END

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