Litcius/Paper detail

Data‐Driven Discovery of Fokker‐Planck Equation for the Earth's Radiation Belts Electrons Using Physics‐Informed Neural Networks

Enrico Camporeale, George Wilkie, Alexander Drozdov, Jacob Bortnik

2022Journal of Geophysical Research Space Physics27 citationsDOIOpen Access PDF

Abstract

Abstract We use the framework of Physics‐Informed Neural Network (PINN) to solve the inverse problem associated with the Fokker‐Planck equation for radiation belts' electron transport, using 4 years of Van Allen Probes data. Traditionally, reduced models have employed a diffusion equation based on the quasilinear approximation. We show that the dynamics of “killer electrons” is described more accurately by a drift‐diffusion equation, and that drift is as important as diffusion for nearly‐equatorially trapped ∼1 MeV electrons in the inner part of the belt. Moreover, we present a recipe for gleaning physical insight from solving the ill‐posed inverse problem of inferring model coefficients from data using PINNs. Furthermore, we derive a parameterization for the diffusion and drift coefficients as a function of L only, which is both simpler and more accurate than earlier models. Finally, we use the PINN technique to develop an automatic event identification method that allows identifying times at which the radial transport assumption is inadequate to describe all the physics of interest.

Topics & Concepts

Fokker–Planck equationPhysicsStatistical physicsElectronDiffusionDiffusion equationPhysical lawHeavy traffic approximationArtificial neural networkVan Allen radiation beltInverse problemApplied mathematicsComputer scienceMathematical analysisMathematicsQuantum mechanicsPlasmaPartial differential equationArtificial intelligenceStatisticsEconomyService (business)MagnetosphereEconomicsNuclear reactor physics and engineeringAtmospheric and Environmental Gas DynamicsRadiation Therapy and Dosimetry