D
2023
Energy dissipation in astrophysical simulations: results of the Orszag-Tang test problem
KAYANIKHOO, Fatemeh, Miljenko ČEMELJIĆ, Maciek WIELGUS and Włodek KLUŹNIAK
Basic information
Original name
Energy dissipation in astrophysical simulations: results of the Orszag-Tang test problem
Authors
KAYANIKHOO, Fatemeh, Miljenko ČEMELJIĆ (191 Croatia, belonging to the institution), Maciek WIELGUS and Włodek KLUŹNIAK
Edition
Opava, Proceedings of RAGtime 23-25: Workshops on black holes and neutron stars, p. 135-142, 8 pp. 2023
Publisher
Slezská univerzita v Opavě, Fyzikální ústav v Opavě
Other information
Type of outcome
Stať ve sborníku
Field of Study
10308 Astronomy
Country of publisher
Czech Republic
Confidentiality degree
není předmětem státního či obchodního tajemství
Publication form
printed version "print"
RIV identification code
RIV/47813059:19630/23:A0000273
Organization unit
Institute of physics in Opava
Keywords in English
magnetic energy dissipation; Magnetohydrodynamics; numerical simulations; PLUTO; resistivity
Tags
International impact, Reviewed
Links
GX21-06825X, research and development project.
V originále
The magnetic field through the magnetic reconnection process affects the dynamics and structure of astrophysical systems. Numerical simulations are the tools to study the evolution of these systems. However, the resolution, dimensions, resistivity, and turbulence of the system are some important parameters to take into account in the simulations. In this paper, we investigate the evolution of magnetic energy in astrophysical simulations by performing a standard test problem for MHD codes, Orszag-Tang. We estimate the numerical dissipation in the simulations using state-of-the-art numerical simulation code in astrophysics, PLUTO. The estimated numerical resistivity in 2D simulations corresponds to the Lundquist number ≈ 104 in the resolution of 512 × 512 grid cells. It is also shown that the plasmoid unstable reconnection layer can be resolved with sufficient resolutions. Our analysis demonstrates that in non-relativistic magnetohydrodynamics simulations, magnetic and kinetic energies undergo conversion into internal energy, resulting in plasma heating.
Displayed: 25/12/2024 07:10