# Constrained transport and adaptive mesh refinement in the Black Hole   Accretion Code

**Authors:** Hector Olivares, Oliver Porth, Jordy Davelaar, Elias R. Most,, Christian M. Fromm, Yosuke Mizuno, Ziri Younsi, Luciano Rezzolla

arXiv: 1906.10795 · 2019-09-11

## TL;DR

This paper presents advanced numerical techniques, including adaptive mesh refinement and constrained transport algorithms, for accurate and efficient general relativistic magnetohydrodynamic simulations of black hole accretion and jets, aiding observational modeling.

## Contribution

It introduces new AMR and constrained transport methods in BHAC for improved accuracy and computational efficiency in GRMHD simulations of black hole environments.

## Key findings

- AMR reduces computational costs while resolving turbulence.
- Divergence-control methods significantly affect simulation outcomes.
- Successful simulation of relativistic jets from Kerr black holes.

## Abstract

Worldwide very long baseline radio interferometry arrays are expected to obtain horizon-scale images of supermassive black hole candidates as well as of relativistic jets in several nearby active galactic nuclei. This motivates the development of models for magnetohydrodynamic flows in strong gravitational fields. The Black Hole Accretion Code (BHAC) intends to aid with the modelling of such sources by means of general relativistic magnetohydrodynamical (GRMHD) simulations in arbitrary stationary spacetimes. New additions were required to guarantee an accurate evolution of the magnetic field when small and large scales are captured simultaneously. We discuss the adaptive mesh refinement (AMR) techniques employed in BHAC, essential to keep several problems computationally tractable, as well as staggered-mesh-based constrained transport (CT) algorithms to preserve the divergence-free constraint of the magnetic field, including a general class of prolongation operators for face-allocated variables compatible with them. Through several standard tests, we show that the choice of divergence-control method can produce qualitative differences in simulations of scientifically relevant accretion problems. We demonstrate the ability of AMR to reduce the computational costs of accretion simulations while sufficiently resolving turbulence from the magnetorotational instability. In particular, we describe a simulation of an accreting Kerr black hole in Cartesian coordinates using AMR to follow the propagation of a relativistic jet while self-consistently including the jet engine, a problem set up-for which the new AMR implementation is particularly advantageous. The CT methods and AMR strategies discussed here are being employed in the simulations performed with BHAC used in the generation of theoretical models for the Event Horizon Telescope Collaboration.

## Full text

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## Figures

25 figures with captions in the complete paper: https://tomesphere.com/paper/1906.10795/full.md

## References

121 references — full list in the complete paper: https://tomesphere.com/paper/1906.10795/full.md

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Source: https://tomesphere.com/paper/1906.10795