11. Nuclear radiation [COMPLETE]

Question 1

What is the difference in mass when the total mass of a nucleus is less than the sum of its constituent nucleons also known as?

Answer 1

Mass defect or mass deficit

Question 2

What is mass defect or mass deficit defined as?

Answer 2

The difference between the measured mass of a nucleus and the sum total of the masses of its constituents

Question 3

What is mass-energy equivalence?

Answer 3

E=mc^2
Mass can be converted into energy
Energy can be converted into mass

Question 4

What does a mass defect imply?

Answer 4

The mass lost if released as energy.

Question 5

What is binding energy defined as?

Answer 5

The energy required to break a nucleus into its constituent protons and neutrons

Question 6

Is the formation of a nucleus from its constituent nucleons an exothermic or endothermic reaction?

Answer 6

The reaction releases energy hence exothermic reaction

Question 7

What is one unified atomic mass unit or 1u defined as?

Answer 7

The mass of exactly 1/12th of a carbon-12

Question 8

What is 1u equivalent to in MeV?

Answer 8

1u = 931.5 MeV

Question 9

What do you look at when comparing stability of different nuclei?

Answer 9

The binding energy per nucleon

Question 10

What is the binding energy per nucleon defined as?

Answer 10

The binding energy of a nucleus divided by the number of nucleons in the nucleus

Question 11

What does a high binding energy per nucleon indicate?

Answer 11

A higher stability since it requires more energy to pull the nucleus apart

Question 12

What is the most stable element?

Answer 12

Iron with a mass number of 56 and the highest binding energy per nucleon

Question 13

Give the sketch of the graph of the binding energy per nucleon against nucleon number

Answer 13

• Anomaly at He-4
• Don’t start at 0, no such nuclei exist
• Axes and units (MeV)
• Peak at Fe-56

Question 14

What are the trends and anomalies of the binding energy per nucleon against nucleon number graph?

Answer 14

• At low mass numbers: lower binding energy per nucleon, hence, they are generally less stable.
• At high mass numbers: general binding energy per nucleon is high and gradually decreases as mass number increases, hence, more unstable.
• Helium-4, Carbon-12 and Oxygen-16 do not fit into the trends: He-4 is v. stable as it has a high binding energy per nucleon. C-12 & O-16 can be considered as 3 and 4 He-4 bound together.

Question 15

What element are likely to undergo FUSION and why?

Answer 15

The lightest elements (before iron) as their nuclei tend to have a lower binding energy per nucleon, hence, they are generally less stable and have weaker electrostatic forces.

Question 16

What element are likely to undergo FISSION and why?

Answer 16

The heaviest elements (after iron) as they are the most unstable.

Question 17

What is fusion defined as?

Answer 17

When small nuclides that combine together to make larger nuclei, releasing energy

Question 18

What are the conditions for fusion?

Answer 18

• Both nuclei must have high K.E. to over come electrostatic repulsion between protons.
  
  • achieved in a star’s core

Question 19

Outline the process of hydrogen burning

Answer 19

1: 2 protons fuse → 1 proton, 1 neutron + 1 positron, 1 neutrino
2: a proton and the deuterium nucleus join to make He-3
3: 2 He-3 fuse → He-4 + 2 protons ejected

Question 20

What is background radiation is defined as?

Answer 20

Low levels of radiation from environmental sources, which are always present around us

Question 21

What is radiation measured in?

Answer 21

Counts per second in a unit called Becquerel (Bq)

Question 22

What are the two types of background radiation?

Answer 22

• Natural sources (rocks, cosmic rays)
• Man-made sources (radon gas, building materials)

Question 23

What is the corrected count rate?

Answer 23

When we account for the background radiation and subtract it from the readings we taken.

Question 24

How does a radiation detector detect radiation?

Answer 24

• When alpha or beta radiation pass close to an atom, they can deliver enough energy to remove electrons, ionising the atom
• Radiation detectors work by detecting the presence of either these ions, or the chemical changes that they produce

Question 25

What are radioactive nuclei?

Answer 25

When unstable nuclei emit particles and/or EM radiation to become stable

Question 26

What are alpha particles?

Answer 26

Alpha (α) particles are high energy particles made up of 2 protons and 2 neutrons

4
α
2

Question 27

What emits alpha particles?

Answer 27

Usually emitted from nuclei that ar very large.

Question 28

What are beta(-) particles?

Answer 28

Beta (β−) particles are high energy electrons emitted from the nucleus

0
β
-1

Question 29

What emits beta(-) particles?

Answer 29

Nuclei that have too many neutrons

Question 30

How ionising are beta particles?

Answer 30

They are moderately ionising due it having a charge of +1e, meaning it can do some slight damge to cells.

Question 31

How penetrating are beta particles?

Answer 31

They are moderately penetrating, having a range of around 20 cm - 3 m in air, depending on their energy and can be stopped by a few millimetres of aluminium foil

Question 32

What are gamma rays?

Answer 32

Gamma (γ) rays are high energy electromagnetic waves (less than 10^-10)

0
γ
0

Question 33

What emits gamma rays?

Answer 33

Nuclei that needs to lose some energy

Question 34

How ionising are gamma rays?

Answer 34

Very ionising, can knock out electrons, cause chemical changes in materials, can damage or kill living cells

Question 35

What is a beta(+) particle?

Answer 35

A high energy positron

Question 36

Give the general equation for alpha decay

Answer 36

A A-2 4
X → Y + α
Z Z-2 2

Question 37

Give the general equation for beta minus decay

Answer 37

A A 0
X → Y + β
Z Z+1 -1
OR
A A
X → Y + e- + antineutrino
Z Z+1

Question 38

Give the general equation for beta plus decay

Answer 38

A A 0
X → Y + β
Z Z-1 +1
OR
A A
X → Y + e+ + neutrino
Z Z-1

Question 39

Give the general equation for gamma decay

Answer 39

A A 0
X → Y + γ
Z Z 0

Question 40

What is radioactive decay is defined as?

Answer 40

The random spontaneous decay of a unstable nucleus to form a more stable nucleus, resulting in the emission of an alpha, beta or gamma particle

Question 41

What is a spontaneous process is defined as?

Answer 41

A process which cannot be influenced by environmental factors

Question 42

What is a random process is defined as?

Answer 42

A process in which the exact time of decay of a nucleus cannot be predicted

Question 43

Is it possible to predict how many nuclei decay in a given time?

Answer 43

Yes as the chance to decay is a constant probabality

Question 44

What s the average decay time?

Answer 44

The average number of nuclei which are expected to decay per unit time

Question 45

What is the decay constant (λ) is defined as

Answer 45

The probability, per second, that a given nucleus will decay

Question 46

What is activity?

Answer 46

The number of decays per unit time

Question 47

What is activity measured in?

Answer 47

Becquerels (Bq) = one decay per second, or 1 s-1

Question 48

What is half-life is defined as?

Answer 48

The time taken for half the number of nuclei in a sample to decay