Abstract
Using fission track analysis (FTA) in conjunction with a composite theoretical model of the transport of plutonium (Pu) in the human body creates a new opportunity to estimate the exposure and dose to the general population due to plutonium in the environment. For the purposes of this study, data derived from FTA performed at the University of Utah's Center for Excellence in Nuclear Technology, Engineering and Research (CENTER) has been used to predict doses for two populations. Both population groups have no known history of plutonium exposures. Therefore, two exposure scenarios (acute and chronic) were assumed to provide boundaries for dose estimates. Dose predictions focus on equivalent dose to lung, liver, and skeletal systems and range from 0.01 mSv to 560 mSv as a function of organ, sample collection interval and exposure type. Additionally, these reconstructions demonstrate the sensitivity of dose calculations to time of sample collection and duration of exposure. As anticipated for a class Y particle, the predicted average equivalent tissue dose to the lungs represents the highest dose to the evaluated compartments. Furthermore, the data imply that the general population receives a dose one order of magnitude lower than a radiation worker with no history of exposure for the equivalent exposure scenario.
Published Version
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call