Radioactive Decay

Question 1

Radioactive Decay

Answer 1

The process by which unstable nuclei reach a more stable configuration.

Question 2

Radioactivity

Answer 2

Process by which unstable nucleus (parent) decays into a new nuclear configuration (daughter) that may be stable or unstable.

Question 3

What are the 4 main modes of radioactive decay?

Answer 3

1. Alpha Decay
2. Beta Decay (+, -, EC)
3. Gamma Decay (Pure, IC)
4. Spontaneous Fission

Question 4

Explain Alpha Decay

Answer 4

Occurs When: Strong nuclear force cannot hold large nucleus together (Z>83). Alpha Decay reduces mass, high particle stability configuration (2p, 2n) causes Alpha particle clusters in nucleus. More energetically favorable to emit alpha particles.
Process:
- energetic alpha particle is emitted
- atomic number Z of parent decreases by 2, atomic mass A decreases by 4
- causes increased neutron/proton ratio

Question 5

Describe Alpha Particles

Answer 5

• very stable configuration
• emission is monoenergetic
• heavy
• charged
• high LET
• short range
• densely ionizing, rapid energy loss through collisions with electrons after emission

Question 6

Explain Beta - Decay

Answer 6

Occurs When: Neutron rich radioactive parent needs more protons and less neutrons to become stable.
Process:
- parent nucleus transforms neutron into a proton
- electron (b- particle) + anti neutrino share available energy and are ejected from nucleus
- atomic number Z of parent nucleus increases by 1, atomic mass A remains the same
- daughter is an isobar of parent

Question 7

Describe Beta - Particles

Answer 7

• charged, electron (-1)
• light
• low LET
• medium range
• undergo collisions after ejection until all kinetic energy is lost, mostly with electrons but some with nucleus resulting in x-rays

Question 8

Explain Beta + Decay

Answer 8

Occurs When: Proton rich radioactive parent needs more neutrons and less protons.
Process:
- parent nucleus transofrms a proton into a neutron
- positron (b+ particle) + neutrino share available energy and are ejected from nucleus
- atomic number Z of parent decreases by 1, atomic mass A remains the same
- daughter is an isobar of parent

Question 9

Describe Beta + Particles

Answer 9

• charged, positron (+1)
• light
• low LET
• medium range
• Positron is annihilated after ejection by a free electron. Masses disappear and 2 photons are emitted travelling in opposite directions.

Question 10

Explain Electron Capture

Answer 10

Occurs When: Beta + Decay requires energy to create extra mass (mass of neutron and positron is greater than mass of proton), when this energy is not available electron capture occurs.
Process:
- nucleus captures atomic orbital shell electron 9usualy k-shell)
- proton in nucleus transforms into neutron
- neutrino is ejected
- atomic number Z of parent decreases by 1, atomic mass A remains the same
- daughter is an isobar of parent

Question 11

Describe Electron Capture Particles

Answer 11

• no specific particle is emitted
• a very weakly interacting neutrino particle is ejected
• low energy gamma rays and characteristic x-rays follow process due to k-shell vacancy

Question 12

Explain Gamma Decay

Answer 12

Occurs When: Nucleus decays from excited state to lower state (commonly after Beta or Alpha Decay)
Process:
- Gamma rays = high energy photons
- emitted when nucleus decays from excited to lower state
- atomic number Z and atomic mass A remain the same