Abstract
The radiological implications of ingestion of nuclear fuel fragments present in the marine environment around Dounreay have been reassessed by using the Monte Carlo code MCNP to obtain improved estimates of the doses to target cells ill the walls of the lower large intestine resulting from the passage of a fragment. The approach takes account of the reduction in dose due to attenuation within the intestinal wall and self-absorption of radiation in the fuel fragment itself. In addition. dose is calculated on the basis of a realistic estimate of the anatomical volume of the lumen, rather that) being based on the average mass of the contents, as in the current ICRP model. Our best estimates of doses from (he ingestion of the largest Dounreay particles are at least a factor of 30 lower than those predicted using the current ICRP model. The new ICRP model will address the issues raised here and provide improved estimates of dose.
Original language | English |
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Pages (from-to) | 49-54 |
Number of pages | 6 |
Journal | Radiation Protection Dosimetry |
Volume | 105(1-4) |
Publication status | Published - 1 Jan 2003 |