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Ionising radiation

Environmental Radioactivity - Medicine - Occupational Radiation Protection - Nuclear Hazards Defence

Ionisierende Strahlung

What is ionising radiation?

Radiation - emanating from a radiation source - transports energy. The energy is transported in the form of electromagnetic waves (as with X-radiation) or as particle flow (as with alpha or beta radiation for example).

In the case of ionising radiation more energy is transported (per photon) as with visible light or with infrared radiation (thermal radiation). Matter penetrated by ionising radiation can thus be altered. To be more specific, atoms and molecules are ionised in the process, which means that electrons are "ejected" from the shells of atoms or molecules. The residual atom or molecule is then (at least for a short time) electrically positively charged. Electrically charged particles are called ions.

When ionising radiation hits living cells or organisms, these ionisation processes or other alterations in molecules can cause more or less severe damage to cells and organisms.

Ionising radiation and radioactivity

Ionising radiation can be generated artificially (X-radiation) or occurs when certain atomic nuclei undergo radioactive decay (alpha, beta, gamma and neutron radiation). If certain atomic nuclei transform themselves into other nuclei without any external influence and emit high-energy radiation (ionising radiation) during the transformation, this characteristic is referred to as radioactivity. The process of nuclear transformation is defined as radioactive decay. The radioactive atomic nuclei are known as radionuclides.

Also when atomic nuclei are split, for example in the fuel rods of a nuclear reactor, ionising radiation is generated in addition to the fission products.

Depending on the starting material, stable or radioactive decay products are formed which can, for their part, further disintegrate. Radioactive substances continue emitting ionising radiation until the "last" radionuclide has decayed.

Types of ionising radiation

Alpha radiationshow / hide

Alpha radiation is particle radiation consisting of two protons and two neutrons. Hence, an alpha particle is a nucleus of the element helium. Alpha particles are absorbed very quickly by matter (by air and water, for example) and for this reason have only a very short range (a few centimetres in air; less than a millimetre in water). They can already be shielded by a sheet of paper.

With external exposure, alpha radiation can only penetrate the outer layers of human skin. Inhaling or ingesting alpha-ray emitters – that is, radioactive substances that emit alpha particles during decay – into the body (incorporation) by air or food can lead to a considerable radiation exposure.

As alpha particles lose their energy within a very short distance, they cause especially severe damage to tissue.

A typical and important example for the incorporation of alpha-ray emitters is the intake of radon and its progeny via inhaled air.

Beta radiationshow / hide

Beta radiation is particle radiation that occurs when radioactive atomic nuclei emit (negatively charged) electrons or – less often – positrons (positively charged particles with the same mass as electrons) as they decay. Beta radiation is much less easily absorbed by matter than alpha radiation and thus has a longer range: The penetration performance of beta particles ranges from a few centimetres to metres in air, a few millimetres to centimetres in soft tissue and plastic. Beta radiation can be shielded quite easily, for example, by an aluminium sheet a few millimetres thick.

Radioactive particles which emit beta radiation can also lead to a considerable radiation exposure when they are taken up by the body (incorporated) via inhaled air or food intake. In the case of external exposure, beta radiation can also damage body tissue as it can penetrate the body even if not very deeply. However, it loses significantly less energy over a certain distance than alpha radiation. We say that beta radiation has a lower biological effectiveness than alpha radiation.

Neutron radiationshow / hide

Neutron radiation consists of uncharged particles (the neutrons). Neutrons are mainly released during nuclear fission, which is a special type of nuclear transformation. Nuclear fission is characteristic only of heavy atomic nuclei (such as nuclei of the element uranium).

Neutron radiation is barely absorbed by air. Shielding is rather elaborate. Materials with the highest possible hydrogen content (such as paraffin, polyethylene, water) are used to initially slow down the neutrons. The slowed-down (thermal) neutrons have to be captured by an absorber (such as boron or cadmium). The gamma radiation emitted simultaneously has to be shielded by lead.

Especially due to the strong interaction with biological tissue (in particular the contained water molecules) neutron radiation has a high biological effectiveness.

Gamma radiationshow / hide

In the case of gamma radiation, energy is transferred as an electromagnetic wave. Electromagnetic radiation can be described in terms of its frequency or its wavelength. The higher the frequency and the shorter the wavelength, the more energetic the radiation. Gamma radiation is at the high energy end of the "electromagnetic spectrum", at the high frequency or short wavelength end.

Gamma radiation results from the decay of radioactive atoms in the atomic nucleus, often in addition to alpha or beta radiation. It penetrates matter very easily. For this reason shielding is elaborate. Heavy materials such as lead and concrete are used.

Both in the case of external exposure and incorporation, gamma radiation is harmful to living beings as it penetrates deeply into tissue. However, its biological effectiveness is lower than that of alpha radiation for instance, as it transfers less energy to tissue over a certain distance.

X-Radiationshow / hide

X-radiation is electromagnetic radiation. It results i.a. from the decay of radioactive atomic nuclei in the atomic shell.

In addition, it can be generated artificially when high-speed electrons are slowed down at the anode (positively charged electrode) of an x-ray tube. The higher the applied tube voltage at which the electrons in the x-ray tube are accelerated, the shorter the wavelength and the higher the energy of the resulting x-radiation.

When the X-ray machine is turned off, no X-radiation is generated.

State of 2017.02.13

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