Neutron protection

Question 1

How can neutrons be liberated from Be-9? Why is Be-9 a good neutron liberation candidate?

Answer 1

• Alpha or proton irradiation.
• Be-9 has a low binding energy per nucleon.

Question 2

How are neutron therapy beams typically created? What else needs to be considered aside from the neutron beam created?

Answer 2

• Cyclotron-produced protons are directed towards a Be target.
• OR Deuterium is directed onto a Tritium target.
• Gamma rays from activation products need also to be considered.

Question 3

What is photodisintegration? What does it depend on?

Answer 3

• A high energy addition to other photon interactions (Rayleigh scattering, photoelectric effect, Compton scattering and pair production). A high energy photon of sufficient energy (~10 MV) passes through the electron cloud, interacting with the target nucleus and causing a photoneutron (or possibly a proton or alpha particle at higher energies) to be ejected. The recoiling nucleus, therefore, has a changed mass number and/or atomic number.
• A higher energy incident photon results in a higher energy photoneutron. The energy of the photoneutron also depends on the target material.

Question 4

What hazards do neutrons present in a linac room?

Answer 4

Neutrons and activation products can contribute directly and indirectly towards patient dose. They can present hazards in the vicinity of the treatment head and the linac entrance maze.

Question 5

What are the different kinds of neutrons at different energies? What are their energy ranges? How do each most commonly interact with mater?

Answer 5

Energy from low to high:
- Thermal (<0.4 eV) - neutron capture.
- Intermediate (0.4 eV - 200 keV) - Elastic scattering.
- Fast (200 keV - 10 MeV) - Elastic scattering with inelastic scattering at increased energies.
- Relativistic (> 10 MeV) - Inelastic scattering resulting in ejection of protons/neutrons.

Question 6

How to neutrons interact with matter?

Answer 6

• Elastic scattering.
• Inelastic scattering.
• Capture.
• Non-elastic reactions.
• Fission.

Question 7

How to neutron elastic and inelastic scattering differ?

Answer 7

• Elastic scattering: Target nucleus recoils after interaction with incident neutron but is not left in an excited state and the total energy of the system remains constant.
• Inelastic scattering: Total energy of scattered neutron and recoil nucleus is less than the incident neutron and the nucleus is left in an excited state. The nucleus may decay via gamma ray emission or remain metastable.

Question 8

What is neutron capture?

Answer 8

A target nucleus captures an incident neutron and forms a compound nucleus left in an excited state. Excitation energy may be released in the form of one or more gamma rays. Some elements have a high cross-section for thermal neutron capture and others show resonance capture.

Question 9

What are neutron non-elastic reactions?

Answer 9

A target nucleus captures an incident neutron causing the emission of a variety of particles (e.g. protons, deuterons, alpha particles etc.).

Question 10

How do neutrons cause fission?

Answer 10

Interactions of neutrons with fissile nuclei cause the formation of compound nuclei which can split into two fission fragments and one or more neutrons.

Question 11

Why do neutrons have an increased biological effect when compared to photons?

Answer 11

Neutrons have a high linear energy transfer meaning more energy is deposited per unit length. This results in more double strand breaks and less repair.

Question 12

What is the radiation weighting factor for neutrons?

Answer 12

The radiation weighting factor for neutrons is variable depending on the neutron energy.

Question 13

What options are available for neutron personal dosimetry?

Answer 13

• Thermoluminescent albedo dosimeters.
• Electrochemically etched plastics.
• Bubble dosimeters.

Question 14

How does a thermoluminescent albedo neutron dosimeter work? What are some advantages and disadvantages?

Answer 14

• Neutrons entering the human body are moderated and backscattered creating neutron fluence at the body surface (typically in the thermal and intermediate ranges). These can be detected by a LiF TLD chip designed to detect thermal neutrons. The dose measured depends on the shape/size of the dosimeter encapsulation and detector distance from the body.

Advantages:
- No energy threshold.
- Large dose range.
- Little influence of body size on on dosimeter reading.
- Acceptable gamma dose discrimination.
- Low dependence on direction of incident radiation.

Disadvantages:
- Low response to fast neutrons.
- High contribution to thermal neutrons.

Question 15

How do electrochemically etched plastic neutron dosimeters work? What are some advantages and disadvantages?

Answer 15

• Neutrons cause a path of damaged molecules in the material. The tracks can then be detected by some etching process. This requires a calibration of the track density to neutron dose equivalent.

Advantages:
- Effective fast neutron response.
- Low neutron energy threshold.
- Photon insensitivity.

Disadvantages:
- Results can vary by dosimeter batch.
- Significant angular dependence.
- Sensitivity.
- Under responds for certain energy ranges (best at the lower and higher ends).

Question 16

How do bubble neutron dosimeters work? What are some advantages and disadvantages?

Answer 16

• Consist of a small container filled with superheated Freon droplets interspread within a clear polymer. Recoil protons produced by neutron interactions with the polymer can strike Freon droplets and vaporise them. They then remain as a trapped visible bubble within the polymer which can be detected. Pressurising the container allows the dosimeter to be reset.

Advantages:
- Sensitive.
- No electronics required.
- Cannot be disturbed by electromagnetic interference.
- Insensitive to photons.

Disadvantages:
- Temperature dependence.
- Shock sensitivity.
- Short periods (few days) of dose accumulation sensitivity.

Question 17

How is the neutron attenuation coefficient calculated?

Answer 17

Attenuation coefficient = Atoms per unit volume x Cross section.

Question 18

How does neutron cross-section depend on atom size? Is the neutron cross-section for hydrogen small or large?

Answer 18

• Generally, the neutron cross-section generally decreases with increasing atomic number, although this is not a strict relationship.
• The neutron cross-section for hydrogen is large as there is limited shielding from the surrounding electron cloud so neutrons can interact directly with the nucleus.

Question 19

Why is boron a good material for detecting and shielding against neutrons?

Answer 19

It has a high neutron cross section.

Question 20

How do boron tri-fluoride detectors work?

Answer 20

Neutrons interact with boron atoms in the boron tri-fluoride gas. This produces Li-7 ions and alpha particles. These can be collected and counted due to their charge. The detector voltage must be set in the proportional range to enable lower gamma peaks to be discriminated.

Question 21

What kind of neutrons are boron tri-fluoride detectors most sensitive to? How can other types of neutrons be detected?

Answer 21

• Thermal neutrons.
• Polythene can be used to moderate the most energetic neutrons to thermal energies.

Question 22

How is an mSv/hr value determined from neutron detector measurements?

Answer 22

Calibration with a known flux of neutrons to convert to dose at 10 mm depth in an ICRU sphere.

Question 23

How do Bonner sphere neutron detectors work?

Answer 23

Detector (e.g. TLD, scintillation, gold foils) are placed at the centre of a series of polythene moderating spheres, each of which uniquely modifies the neutron spectrum for detection. This allows for spectral measurements to be undertaken.

Question 24

What can influence patient neutron dose in radiotherapy?

Answer 24

• Beam energy.
• Geometry, collimator setting etc.
• Treatment type (e.g. may be enhanced for total body irradiation).
• Neutron backscattering from metal shielding in primary barrier.

Question 25

When may neutron shielding be required to protect staff/the public outside of the bunker? What shielding materials might be used in these cases?

Answer 25

• Higher energy linac beams.
• Boronated polyethene or lithium salts with a high hydrogen content could be used due to their high interaction cross-section meaning neutrons would be attenuated.

Question 26

How can maintenance engineers working on linac head components be protected from neutron activated materials?

Answer 26

Neutron activated materials in the linac head are short lived. Therefore, employing systems of work to ensure maintenance work is not started for some time after a radiation exposure will protect maintenance staff.

Question 27

What may contribute to electronic failure of linac equipment?

Answer 27

Neutron interactions.