Kim, Y.-H.Yiacoumi, S.Nenes, AthanasiosTsouris, C.2018-10-152018-10-152018-10-15201710.1016/j.jaerosci.2017.09.024https://infoscience.epfl.ch/handle/20.500.14299/148866Compositional changes by the decay of radionuclides in radioactive aerosols can influence their charging state, coagulation frequency and size distribution throughout their atmospheric lifetime. The importance of such effects is unknown as they have not been considered in microphysical and global radioactivity transport studies to date. We explore the effects of compositional changes on the charging efficiency and coagulation rates of aerosols using a set of kinetic equations that couple all relevant processes (decay, charging and coagulation) and their evolution over time. Compared to a coupled aggregation-tracer model for the prediction of the radioactive composition of particulates undergoing coagulation, our kinetic approach can provide similar results using much less central processing unit time. Together with other considerations, our approach is computational efficient enough to allow implementation in 3D atmospheric transport models. The decay of radionuclides and the production of decay products within radioactive aerosols may significantly affect the aerosol charging rates, and either hinder or promote the coagulation of multicomponent radioactive aerosols. These results suggest that radiological phenomena occurring within radioactive aerosols, as well as subsequent effects on aerosol microphysics, should be considered in regional and global models to more accurately predict radioactivity transport in the atmosphere in case of a nuclear plant accident. © 2017 Elsevier LtdAerosol chargingAerosol coagulationGaussian charge distributionsMulticomponent radioactive aerosolsNuclear plant accidentsRadioactive decayRadioactivity transportAccidentsAerosolsAtmospheric aerosolsCoagulationIntegral equationsNuclear reactor accidentsProgram processorsRadiationRadioactivityRadioisotopesAerosol chargingAerosol coagulationGaussiansNuclear plantRadioactive aerosolsRadioactive decayAtmospheric movementsradioactive aerosolradioisotopetraceraerosolatmospheric transportcoagulationGaussian methodnuclear accidentpollutant transportradioactive decayradioactive pollutionradioactivitysize distributiontracerArticleatmosphereatmospheric radioactivityatmospheric transportblood clottingchemical compositioncontrolled studydynamicskineticsnuclear power plantpredictionpriority journalradioisotope decaytimetext::journal::journal article::research article