Numerical simulations of super-critical black hole accretion flows in general relativity - INSPIRE

DataBETA

Numerical simulations of super-critical black hole accretion flows in general relativity

Nov 22, 2013

18 pages

Published in:

Mon.Not.Roy.Astron.Soc. 439 (2014) 1, 503-520

Published: Mar 21, 2014

e-Print:

1311.5900 [astro-ph.HE]

DOI:

10.1093/mnras/stt2479

View in:

ADS Abstract Service

reference search246 citations

Citations per year

Abstract: (Oxford University Press)

A new general relativistic radiation magnetohydrodynamical code koral is described, which employs the M1 scheme to close the radiation moment equations. The code has been successfully verified against a number of tests. Axisymmetric simulations of super-critical magnetized accretion on non-rotating (a_* = 0.0) and spinning (a_* = 0.9) black holes are presented. The accretion rates in the two models are

\dot{M}\approx 100{\rm -}200 \dot{M}_{\rm Edd}

. These first general relativistic simulations of super-critical black hole accretion are potentially relevant to tidal disruption events and hyper-accreting supermassive black holes in the early Universe. Both simulated models are optically and geometrically thick, and have funnels through which energy escapes in the form of relativistic gas, Poynting flux and radiative flux. The jet is significantly more powerful in the a_* = 0.9 run. The net energy outflow rate in the two runs correspond to efficiencies of 5 per cent (a_* = 0) and 33 per cent (a_* = 0.9), as measured with respect to the mass accretion rate at the black hole. These efficiencies agree well with those measured in previous simulations of non-radiative geometrically thick discs. Furthermore, in the a_* = 0.9 run, the outflow power appears to originate in the spinning black hole, suggesting that the associated physics is again similar in non-radiative and super-critical accretion flows. While the two simulations are efficient in terms of total energy outflow, both runs are radiatively inefficient. Their luminosities are only ∼1–10L_Edd, which corresponds to a radiative efficiency ∼0.1 per cent. Interestingly, most of the radiative luminosity emerges through the funnels where the local radiative flux is highly super-Eddington.

Note:

19 pages, 13 figures, submitted to MNRAS

accretion, accretion discs
black hole physics
relativistic processes
methods: numerical
galaxies: jets

References(91)

Figures(21)

Ró˙zánska, A., & Sa¸dowski, A. 2010, Astronomy &

M.A. Abramowicz
,
M. Jaroszy´nski
,
S. Kato
,
J.-P. Lasota

- Astrophysics 521 A15

M.A. Abramowicz
,
X.-M. Chen
,
S. Kato
,
J.-P. Lasota
,
O. Regev

Thermal equilibria of accretion disks

Marek A. Abramowicz
(
- Chalmers U. Tech.
)
,
Xingming Chen
(
- Chalmers U. Tech.
)
,
Shoji Kato
(
- Chalmers U. Tech.
)
,
Jean-Pierre Lasota
(
- Chalmers U. Tech.
)
,
Oded Regev
(
- Technion
)

- Astrophys.J.Lett. 438 (1995) L37
•
e-Print:
- astro-ph/9409018
•
DOI:
- 10.1086/187709

Slim accretion disks

M.A. Abramowicz
(
- SISSA, Trieste and
- Santa Barbara, KITP
)
,
B. Czerny
(
- SISSA, Trieste and
- Leicester U.
)
,
J.P. Lasota
(
- SISSA, Trieste and
- Meudon Observ.
)
,
E. Szuszkiewicz
(
- SISSA, Trieste
)

- Astrophys.J. 332 (1988) 646
•
DOI:
- 10.1086/166683

Cosmos++: relativistic magnetohydrodynamics on unstructured grids with local adaptive refinement

Peter Anninos
(
- LLNL, Livermore
)
,
P.Chris Fragile
(
- UC, Santa Barbara
)
,
Jay D. Salmonson
(
- LLNL, Livermore
)

- Astrophys.J. 635 (2005) 723-740
•
e-Print:
- astro-ph/0509254
•
DOI:
- 10.1086/497294

1978

M.C. Begelman

- Mon.Not.Roy.Astron.Soc. 184 (1978) 53

Radio Monitoring of the Tidal Disruption Event Swift J164449.3+573451. I. Jet Energetics and the Pristine Parsec-Scale Environment of a Supermassive Black Hole

et al.

- Astrophys.J. 748 (2012) 36
•
e-Print:
- 1112.1697
•
DOI:
- 10.1088/0004-637X/748/1/36

1999, Monthly Notices of the Royal

R.D. Blandford
,
M.C. Begelman

Astronomical Society, 303, L1

1977, Monthly Notices of the Royal

R.D. Blandford
,
R.L. Znajek

Astronomical Society, 179, 433

A relativistic jetted outburst from a massive black hole fed by a tidally disrupted star

et al.

- Science 333 (2011) 203
•
e-Print:
- 1104.3257
•
DOI:
- 10.1126/science.1207150

2007, Astronomy &

L. Del Zanna
,
O. Zanotti
,
N. Bucciantini
,
P. Londrillo

- Astrophysics 473 11

Magnetically driven accretion flows in the kerr metric I: models and overall structure

- Astrophys.J. 599 (2003) 1238
•
e-Print:
- astro-ph/0307260
•
DOI:
- 10.1086/379509

Observational Signatures of Tilted Black Hole Accretion Disks from Simulations

- Astrophys.J. 730 (2011) 36
•
e-Print:
- 1101.3783
•
DOI:
- 10.1088/0004-637X/730/1/36

2004, Astrophysics and Space Physics Reviews, 12, 1

S. Fabrika

HARM: A Numerical scheme for general relativistic magnetohydrodynamics

- Astrophys.J. 589 (2003) 444-457
•
e-Print:
- astro-ph/0301509
•
DOI:
- 10.1086/374594

Assessing Quantitative Results in Accretion Simulations: From Local to Global

- Astrophys.J. 738 (2011) 84
•
e-Print:
- 1103.5987
•
DOI:
- 10.1088/0004-637X/738/1/84

Three-dimensional mhd simulations of radiatively inefficient accretion flows

- Astrophys.J. 592 (2003) 1042-1059
•
e-Print:
- astro-ph/0301402
•
DOI:
- 10.1086/375769

2012, Astrophysical Journal

Y.-F. Jiang
,
J.M. Stone
,
S.W. Davis

Suppl. Ser., 199, 14

1999

S.S. Komissarov

- Mon.Not.Roy.Astron.Soc. 303 (1999) 343

Jets from Tidal Disruptions of Stars by Black Holes

- Astrophys.J. 749 (2012) 92
•
e-Print:
- 1111.2802
•
DOI:
- 10.1088/0004-637X/749/1/92

Extracting black-hole rotational energy: The generalized Penrose process

- Phys.Rev.D 89 (2014) 2, 024041
•
e-Print:
- 1310.7499
•
DOI:
- 10.1103/PhysRevD.89.024041

Bloom

Levan A. J.
,
Tanvir N. R.
,
Cenko S. B.
,
Perley D. A.
,
Wiersema K.

1-25 of 91
1
2
3
4
25 / page