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Long timescale numerical simulations of large, super-critical accretion discs

Long timescale numerical simulations of large, super-critical accretion discs
Long timescale numerical simulations of large, super-critical accretion discs
In this paper, we report on three of the largest (in terms of simulation domain size) and longest (in terms of duration) 3D general relativistic radiation magnetohydrodynamic simulations of supercritical accretion on to black holes. The simulations are all set for a rapidly rotating (a = 0.9) stellar-mass (MBH = 6.62M®) black hole. The simulations vary in their initial target mass accretion rates (assumed measured at large radius), with values sampled in the range m˙ = M˙ /M˙Edd = 1–10. We find in practice, though, that all of our simulations settle close to a net accretion rate of m˙net = m˙in − m˙out ≈ 1 (over the radii where our simulations have reached equilibrium), even though the inward mass flux (measured at large radii) m˙ in can exceed 1000 in some cases. This is possible because the outflowing mass flux m˙out adjusts itself to very nearly cancel out m˙in, so that at all radii M˙net ≈ M˙Edd. In other words, these simulated discs obey the Eddington limit. We compare our results with the predictions of the slim disc (advection-dominated) and critical disc (wind/outflow-dominated) models, finding that they agree quite well with the critical disc model both qualitatively and quantitatively. We also speculate as to why our results appear to contradict most previous numerical studies of supercritical accretion
astro-ph.HE, radiation: dynamics, stars: black holes, X-rays: binaries, accretion, accretion discs
1365-2966
2820-2829
Fragile, P. Chris
f919dd22-c0fc-4415-ac5a-953b9a3b2c35
Middleton, Matthew J.
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Bollimpalli, Deepika A.
1ee84860-dddd-481a-ab79-ac4c813cb5da
Smith, Zach
4faabd67-d117-4c73-b00e-1b0860b9cc09
Fragile, P. Chris
f919dd22-c0fc-4415-ac5a-953b9a3b2c35
Middleton, Matthew J.
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Bollimpalli, Deepika A.
1ee84860-dddd-481a-ab79-ac4c813cb5da
Smith, Zach
4faabd67-d117-4c73-b00e-1b0860b9cc09

Fragile, P. Chris, Middleton, Matthew J., Bollimpalli, Deepika A. and Smith, Zach (2025) Long timescale numerical simulations of large, super-critical accretion discs. Monthly Notices of the Royal Astronomical Society, 540 (3), 2820-2829. (doi:10.1093/mnras/staf890).

Record type: Article

Abstract

In this paper, we report on three of the largest (in terms of simulation domain size) and longest (in terms of duration) 3D general relativistic radiation magnetohydrodynamic simulations of supercritical accretion on to black holes. The simulations are all set for a rapidly rotating (a = 0.9) stellar-mass (MBH = 6.62M®) black hole. The simulations vary in their initial target mass accretion rates (assumed measured at large radius), with values sampled in the range m˙ = M˙ /M˙Edd = 1–10. We find in practice, though, that all of our simulations settle close to a net accretion rate of m˙net = m˙in − m˙out ≈ 1 (over the radii where our simulations have reached equilibrium), even though the inward mass flux (measured at large radii) m˙ in can exceed 1000 in some cases. This is possible because the outflowing mass flux m˙out adjusts itself to very nearly cancel out m˙in, so that at all radii M˙net ≈ M˙Edd. In other words, these simulated discs obey the Eddington limit. We compare our results with the predictions of the slim disc (advection-dominated) and critical disc (wind/outflow-dominated) models, finding that they agree quite well with the critical disc model both qualitatively and quantitatively. We also speculate as to why our results appear to contradict most previous numerical studies of supercritical accretion

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Accepted/In Press date: 28 May 2025
e-pub ahead of print date: 31 May 2025
Published date: 13 June 2025
Keywords: astro-ph.HE, radiation: dynamics, stars: black holes, X-rays: binaries, accretion, accretion discs

Identifiers

Local EPrints ID: 503786
URI: http://eprints.soton.ac.uk/id/eprint/503786
DOI: doi:10.1093/mnras/staf890
ISSN: 1365-2966
PURE UUID: e1502e16-cd47-4b81-bb5e-5a760c6588f7

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Date deposited: 13 Aug 2025 16:32
Last modified: 30 Sep 2025 17:25

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Contributors

Author: P. Chris Fragile
Author: Matthew J. Middleton
Author: Deepika A. Bollimpalli
Author: Zach Smith

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