Abstract
During nuclear accidents, decision-makers need to handle considerable data to take appropriate protective actions to protect people and the environment from radioactive material release. In such scenarios, machine learning can be an essential tool in facilitating the protection action decisions that will be made by decision-makers. By feeding machines software with big data to analyze and identify nuclear accident behavior, types, and the concentrations of released radioactive materials can be predicted, thus helping in early warning and protecting people and the environment. In this study, based on the ground deposition concentration of radioactive materials at different distances offsite in an emergency planning zone (EPZ), we proposed classification and regression models for three severe accidents. The objective of the classification model is to recognize the transient situation type for taking appropriate actions, while the objective of the regression model is to estimate the concentrations of the released radioactive materials. We used the Personal Computer Transient Analyser (PCTRAN) Advanced Power Reactor (APR) 1400 to simulate three severe accident scenarios and to generate a source term released to the environment. Additionally, the Radiological Consequence Analysis Program (RCAP) was used to assess the off-site consequences of nuclear power plant accidents and to estimate the ground deposition concentrations of radionuclides. Moreover, ground deposition concentrations at different distances were used as input data for the classification and regression tree (CART) models to obtain an accident pattern and to establish a prediction model. Results showed that the ground deposition concentration at a near distance from a nuclear power plant is a more informative parameter in predicting the concentration of radioactive material release, while the ground deposition concentration at a far distance is a very informative parameter in identifying accident types. In the regression model, the R-square of the training and test data was 0.995 and 0.994, respectively, showing a mean strong linear relationship between the predicted and actual concentration of radioactive material release. The mean absolute percentage error was found to be 26.9% and 28.1% for the training and test data, respectively. In the classification model, the model predicted a scenario (1) of 99.8% and 98.9%, scenario (2) of 98.4% and 91.6%, and scenario (3) of 98.6% and 94.7% for the training and test data, respectively.
Highlights
The ground deposition concentration was calculated for the three accidents scenarios at different distances and with 11 years of meteorological data
We will present the results of one year, 2020, to explain the ground deposition behavior
The three scenarios can be classified at level 7 of the International Nuclear and Radiological Event Scale (INES), where significant radioactive materials are released into the environment along with their subsequent health and environmental impacts that require the initiation of public protective actions at an earlier stage in the event of nuclear emergency
Summary
Nuclear energy is considered to be one of the cleanest energy sources due to its low emission of greenhouse gases. It is a baseload power with a steady and huge output unlike other renewable energies, such as solar and wind energies [1]. Throughout the history of nuclear energy, there have been three notorious nuclear accidents: Chernobyl, Three Mile Island (TMI), and Fukushima. The potential hazards associated with nuclear power plants have been a major concern among people due to the huge amounts of released radioactive materials during nuclear disasters, which significantly affect humans and the environment [2,3,4]. The identification of nuclear accidents and estimating the Sustainability 2021, 13, 9712.
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