Litcius/Paper detail

Solving the pulsar equation using physics-informed neural networks

Petros Stefanou, Jorge F. Urbán, J. A. Pons

2023Monthly Notices of the Royal Astronomical Society12 citationsDOIOpen Access PDF

Abstract

ABSTRACT In this study, Physics-Informed Neural Networks (PINNs) are skilfully applied to explore a diverse range of pulsar magnetospheric models, specifically focusing on axisymmetric cases. The study successfully reproduced various axisymmetric models found in the literature, including those with non-dipolar configurations, while effectively characterizing current sheet features. Energy losses in all studied models were found to exhibit reasonable similarity, differing by no more than a factor of three from the classical dipole case. This research lays the groundwork for a reliable elliptic Partial Differential Equation solver tailored for astrophysical problems. Based on these findings, we foresee that the utilization of PINNs will become the most efficient approach in modelling three-dimensional magnetospheres. This methodology shows significant potential and facilitates an effortless generalization, contributing to the advancement of our understanding of pulsar magnetospheres.

Topics & Concepts

PhysicsPulsarRotational symmetryGeneralizationSolverDipolePartial differential equationRange (aeronautics)Statistical physicsAstrophysicsTheoretical physicsApplied mathematicsAerospace engineeringMathematical analysisMechanicsQuantum mechanicsComputer scienceProgramming languageMathematicsEngineeringModel Reduction and Neural NetworksPulsars and Gravitational Waves ResearchMeteorological Phenomena and Simulations