Radiation protection

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Radiation protection, sometimes known as radiological protection, is the science of protecting people and the environment from the harmful effects of ionizing radiation, which includes both particle radiation and high energy electromagnetic radiation.

Ionizing radiation is widely used in industry and medicine, but presents a significant health hazard. It causes microscopic damage to living tissue, resulting in skin burns and radiation sickness at high exposures and cancer, tumors and genetic damage at low exposures.

Contents 1 Types 1.1 Occupational 1.2 Practical 2 Shielding design 3 ALARP 4 See also 5 References 6 External links

[edit] Types

[edit] Occupational

It includes occupational radiation protection, which is the protection of workers; medical radiation protection, which is the protection of patients; and public radiation protection, which is about protection of individual members of the public, and of the population as a whole.

There are three factors that control the amount, or dose, of radiation received from a source. Radiation exposure can be managed by a combination of these factors:

1. Time: Reducing the time of an exposure reduces the effective dose proportionally. An example of reducing radiation doses by reducing the time of exposures might be improving operator training to reduce the time they take to handle a source.
2. Distance: Increasing distance reduces dose due to the inverse square law. Distance can be as simple as handling a source with forceps rather than fingers.
3. Shielding: Adding shielding can also reduce radiation doses. The radiation getting through falls exponentially with the thickness of the shield. In x-ray facilities, the plaster on the rooms with the x-ray generator contains barium sulfate and the operators stay behind a leaded glass screen and wear lead aprons. Almost any material can act as a shield from gamma or x-rays if used in sufficient amounts (see below).

[edit] Practical

Practical radiation protection tends to be a job of juggling the three factors to identify the most cost effective solution.

In some cases, improper shielding can actually make the situation worse, when the radiation interacts with the shielding material and creates secondary radiation that absorbs in the organisms more readily.

Different types of ionizing radiation behave in different ways, so different shielding techniques are used.

• Particle radiation consists of a stream of charged or neutral particles, both charged ions and subatomic elementary particles. This includes solar wind, cosmic radiation, and neutron flux in nuclear reactors.
  • Alpha radiation (helium nuclei) is the easiest to shield. Even very energetic alpha particles can be stopped with a leaf of paper.
  • Beta radiation (electrons) is more difficult, but still a relatively thin layer of aluminum can usually do the job. However, in cases where high energy beta particles are emitted (e.g. ³²P), the Bremsstrahlung produced by shielding this radiation with the normally used materials is itself dangerous; in such cases, shielding must be accomplished with low density materials, e.g. plastic, wood, water or acrylic glass (Plexiglas, Lucite) [1].
  • In case of beta+ radiation (positrons) the gamma radiation from the electron-positron annihilation reaction poses additional concern.
  • Neutron radiation is not as readily absorbed as charged particle radiation. Neutrons are absorbed by nuclei of atoms in a nuclear reaction (which often leads to emission of gamma photons, causing additional shielding concerns), but fast neutrons have first to be slowed down (moderated) to slower speeds, by inelastic collisions with heavy nuclei or by elastic collisions with light ones. A large mass of hydrogen-rich material, eg. water (or concrete, which contains a lot of chemically-bound water), polyethylene, or paraffin wax is commonly used. It can be further combined with boron for more efficient absorption of the thermal neutrons.
  • Cosmic radiation is not a common concern, as the Earth's atmosphere absorbs it and the magnetosphere acts as a shield, but it poses a problem for satellites and astronauts. While satellite electronics can be radiation hardened, astronauts can't, so they have to be shielded. Because weight is a premium on space technology, methods alternative to absorption are being proposed, such as magnetic shielding using superconductors.[2][3] Aircrews and frequent fliers are also at a slight risk.
• Electromagnetic radiation consists of emissions of electromagnetic waves, the properties of which depend on the wavelength.
  • X-ray and gamma radiation are best absorbed by atoms with heavy nuclei; the heavier the nucleus, the better the absorption. In some special applications, depleted uranium is used, but lead is much more common. Barium sulfate is used in some applications too. However, when cost is important, almost any material can be used, but it must be far thicker. Most nuclear reactors use thick concrete shields to create a bioshield with a thin water cooled layer of lead on the inside to protect the porous concrete from the coolant inside.
  • Ultraviolet (UV) radiation is ionizing but it is not penetrating, so it can be shielded by thin opaque layers such as sunscreen, clothing, and protective eyewear. Protection from UV is simpler than for the other forms of radiation above, so it is often considered separately.

[edit] Shielding design

Shielding reduces the intensity of radiation exponentially depending on the thickness. A standard measure of the effectiveness of a shielding material is the halving thickness or half value layer, , the thickness that reduces gamma or x-ray radiation by half. If is the intensity of radiation on the source side and is the thickness of the shield, the intensity of radiation that gets through, , is:

This means when added thicknesses are used, the shielding multiplies. For example, a practical shield in a fallout shelter is ten halving-thicknesses of packed dirt, which is 90 cm (3 ft) of dirt. This reduces gamma rays by a factor of 1/1,024, which is 1/2 multiplied by itself ten times. Halving thicknesses of some materials, that reduce gamma ray intensity by 50% (1/2) include (see Kearney, ref):

• 9 cm (3.6 inches) of packed soil
• 6 cm (2.4 inches) of concrete
• 1 cm (0.4 inches) of lead
• 0.2 cm (0.08 inches) of depleted uranium
• 150 m (500 ft) of air

The effectiveness of a shielding material in general increases with its density.

[edit] ALARP

ALARP, is an acronym for an important principle in exposure to radiation and other occupational health risks and stands for "As Low As Reasonably Practical". The aim is to minimize the risk of radioactive exposure or other hazard while keeping in mind that some exposure may be acceptable in order to further the task at hand. The equivalent term ALARA, "As Low As Reasonably Achievable", is also commonly used.

This compromise is well illustrated in radiology. The application of radiation can aid the patient by providing doctors and other health care professionals with a medical diagnosis, but the exposure should be reasonably low enough to keep the statistical probability of cancers or sarcomas (stochastic effects) below an acceptable level, and to eliminate deterministic effects (eg. skin reddening or cataracts). An acceptable level of incidence of stochastic effects is considered to be equal for a worker to the risk in another work generally considered to be safe.

This policy is based on the principle that any amount of radiation exposure, no matter how small, can increase the chance of negative biological effects such as cancer, though perhaps by a negligible amount. It is also based on the principle that the probability of the occurrence of negative effects of radiation exposure increases with cumulative lifetime dose. These ideas are combined to form the linear no-threshold model. At the same time, radiology and other practices that involve use of radiations bring benefits to population, so reducing radiation exposure can reduce the efficacy of a medical practice. The economic cost, for example of adding a barrier against radiation, must also be considered when applying the ALARP principle.

There are four major ways to reduce radiation exposure to workers or to population:

• Shielding. Use proper barriers to block or reduce ionizing radiation.
• Time. Spend less time in radiation fields.
• Distance. Increase distance between radioactive sources and workers or population.
• Amount. Reduce the quantity of radioactive material for a practice.

[edit] See also

• Demron, a radiation shielding polymer
• Ducrete
• Fallout shelter
• Lead shielding
• List of nuclear accidents
• Nuclear safety
• Stopping power (particle radiation)
• Radiological protection of patients
• National Council on Radiation Protection and Measurements
• Whole body counting

[edit] References

• Harvard University Radiation Protection Office Providing radiation guidance to Harvard University and affiliated institutions.

[edit] External links

• IRPA, International Radiation Protection Association A world-wide association of individuals engaged in radiation protection.
• Radiation protection of patients International Atomic Energy Agency information on the safe use of radiation in medicine.
• ICRP, International Commission on Radiation Protection
• ICRU, International Commission on Radiation Units
• IAEA, International Atomic Energy Agency
• UNSCEAR, United Nations Scientific Committee on the effects of Ionizing Radiations
• HPA (ex NRPB), Health Protection Agency, UK
• NCRP, National Council on Radiation Protection and Measurements, USA
• IRSN, Institute for Radioprotection and Nuclear Safety, France

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