Radiation Effects

DOE-HDBK-1017/2-93 RADIATION EFFECTS IN ORGANIC COMPOUNDS Plant Materials High-density (linear) polyethylene marlex 50 loses both strength and ductility at relatively low doses. In general, rubber will harden upon being irradiated. However, butyl or Thiokol rubber will soften or become liquid with high radiation doses. It is important that oils and greases be evaluated for their resistance to radiation if they are to be employed in a high-radiation environment. Liquids that have the aromatic ring-type structure show an inherent radiation resistance and are well suited to be used as lubricants or hydraulics. For a given gamma flux, the degree of decomposition observed depends on the type of chemical bonding present. The chemical bond with the least resistance to decomposition is the covalent bond. In a covalent bond, the outer, or valence, electrons are shared by two atoms rather than being firmly attached to any one atom. Organic compounds, and some inorganic compounds such as water, exhibit this type of bonding. There is considerable variation in the strength of covalent bonds present in compounds of different types and therefore a wide variation in their stability under radiation. The plastics discussed above can show very sharp property changes with radiation, whereas polyphenyls are reasonably stable. One result of ionization is that smaller hydrocarbon chains will be formed (lighter hydrocarbons and gases) as well as heavier hydrocarbons by recombination of broken chains into larger ones. This recombination of broken hydrocarbon chains into longer ones is called polymerization. Polymerization is one of the chemical reactions that takes place in organic compounds during irradiation and is responsible for changes in the properties of this material. Some other chemical reactions in organic compounds that can be caused by radiation are oxidation, halogenation, and changes in isomerism. The polymerization mechanism is used in some industrial applications to change the character of plastics after they are in place; for example, wood is impregnated with a light plastic and then cross-bonded (polymerized) by irradiating it to make it more sturdy. This change in properties, whether it be a lubricant, electrical insulation, or gaskets, is of concern when choosing materials for use near nuclear reactors. One of the results of the Three Mile Island accident is that utilities have been asked to evaluate whether instrumentation would function in the event of radiation exposure being spread because of an accident. Because neutrons and gamma rays (and other nuclear radiations) produce the same kind of decomposition in organic compounds, it is common to express the effects as a function of the energy absorbed. One way is to state the energy in terms of a unit called the rad. The rad represents an energy absorption of 100 ergs per gram of material. As an example of the effects of radiation, Figure 7 shows the increase in viscosity with radiation exposure (in rads) of three organic compounds that might be considered for use as reactor moderators and coolants. The ordinates represent the viscosity increase relative to that of the material before irradiation (mostly at 100�F), so that they give a general indication of the extent of decomposition due to radiation exposure. This figure illustrates that aromatic hydrocarbons (n-butyl benzene) are more resistant to radiation damage than are aliphatic compounds (hexadecane). The most resistant of all are the polyphenyls, of which diphenyl is the simplest example. MS-05 Page 46 Rev. 0