Magnetic fields during the formation of supermassive black holes

Observations of quasars at z > 6 report the existence of a billion solar mass black holes. Comprehending their formation in such a short time-scale is a matter of ongoing research. One of the most promising scenarios to assemble supermassive black holes is a monolithic collapse of protogalactic g...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2014-05, Vol.440 (2), p.1551-1561
Main Authors: Latif, M. A., Schleicher, D. R. G., Schmidt, W.
Format: Article
Language:English
Subjects:
Astronomy
Black holes
Clouds
Cooling
Gravity
Magnetic fields
Quasars
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Summary:Observations of quasars at z > 6 report the existence of a billion solar mass black holes. Comprehending their formation in such a short time-scale is a matter of ongoing research. One of the most promising scenarios to assemble supermassive black holes is a monolithic collapse of protogalactic gas clouds in atomic cooling haloes with T vir ≥ 104 K. In this paper, we study the amplification and impact of magnetic fields during the formation of seed black holes in massive primordial haloes. We perform high-resolution cosmological magnetohydrodynamic simulations for four distinct haloes and follow their collapse for a few free-fall times until the simulations reach a peak density of 7 × 10−10 g cm−3. Our findings show that irrespective of the initial seed field, the magnetic field strength reaches a saturated state in the presence of strong accretion shocks. Under such conditions, the growth time becomes very short and amplification occurs rapidly within a small fraction of the free-fall time. We find that the presence of such strong magnetic fields provides additional support against gravity and helps in suppressing fragmentation. Massive clumps of a few hundred solar masses are formed at the end of our simulations and high accretion rates of 1 M yr−1 are observed. We expect that in the presence of such accretion rates, the clumps will grow to form supermassive stars of ∼105 M. Overall, the role of the magnetic fields seems supportive for the formation of massive black holes.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stu357