Abstract
In the event of an accidental or intentional hazardous material release in the atmosphere, researchers often run physics-based atmospheric transport and dispersion models to predict the extent and variation of the contaminant spread. These predictions are imperfect due to propagated uncertainty from atmospheric model physics (or parameterizations) and weather data initial conditions. Ensembles of simulations can be used to estimate uncertainty, but running large ensembles is often very time consuming and resource intensive, even using large supercomputers. In this paper, we present a machine-learning-based method which can be used to quickly emulate spatial deposition patterns from a multi-physics ensemble of dispersion simulations. We use a hybrid linear and logistic regression method that can predict deposition in more than 100,000 grid cells with as few as fifty training examples. Logistic regression provides probabilistic predictions of the presence or absence of hazardous materials, while linear regression predicts the quantity of hazardous materials. The coefficients of the linear regressions also open avenues of exploration regarding interpretability—the presented model can be used to find which physics schemes are most important over different spatial areas. A single regression prediction is on the order of 10,000 times faster than running a weather and dispersion simulation. However, considering the number of weather and dispersion simulations needed to train the regressions, the speed-up achieved when considering the whole ensemble is about 24 times. Ultimately, this work will allow atmospheric researchers to produce potential contamination scenarios with uncertainty estimates faster than previously possible, aiding public servants and first responders.
Highlights
There is nothing about our method that is inherently specific to FLEXPART-Weather Research and Forecasting (WRF), and we think this method could work for simulations that are unrelated to deposition
We presented a statistical method that can be used to quickly emulate complex, spatially varying radiological deposition patterns produced by the meteorological and dispersion tools WRF and FLEXPART
Researchers can run FLEXPART-WRF hundreds of times by varying representations of physical processes in the models, but that can take crucial hours
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. One event which is important to public health and national security is the release of hazardous materials from nuclear weapons explosions, nuclear reactor breaches (such as Chernobyl or Fukushima), chemical spills, industrial accidents, and other toxic releases These types of incidents happen suddenly and without warning, creating a plume of toxic material in the earth’s atmosphere or ocean which can threaten the well-being of living organisms and environments. To predict how a toxic plume disperses and deposits throughout the environment, scientists typically run computer simulations These dispersion simulations solve physical and chemical equations to produce evolving concentration and deposition fields, but many of the processes represented in the models are uncertain or not resolved at the scales of interest.
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