Details

Autor(en) / Beteiligte

• Sturm, E
• Dexter, J
• Pfuhl, O
• Stock, M R
• Davies, R I
• Lutz, D
• Clénet, Y
• Eckart, A
• Eisenhauer, F
• Genzel, R
• Gratadour, D
• Hönig, S F
• Kishimoto, M
• Lacour, S
• Millour, F
• Netzer, H
• Perrin, G
• Peterson, B M
• Petrucci, P O
• Rouan, D
• Waisberg, I
• Woillez, J
• Amorim, A
• Brandner, W
• Schreiber, N M Förster
• Garcia, P J V
• Gillessen, S
• Ott, T
• Paumard, T
• Perraut, K
• Scheithauer, S
• Straubmeier, C
• Tacconi, L J
• Widmann, F

Titel

Spatially resolved rotation of the broad-line region of a quasar at sub-parsec scale

Ist Teil von

• Nature (London), 2018-11, Vol.563 (7733), p.657-660

Ort / Verlag

England: Nature Publishing Group

Erscheinungsjahr

2018

Link zum Volltext

Beschreibungen/Notizen

• The broadening of atomic emission lines by high-velocity motion of gas near accreting supermassive black holes is an observational hallmark of quasars . Observations of broad emission lines could potentially constrain the mechanism for transporting gas inwards through accretion disks or outwards through winds . The size of regions for which broad emission lines are observed (broad-line regions) has been estimated by measuring the delay in light travel time between the variable brightness of the accretion disk  continuum and the emission lines -a method known as reverberation mapping. In some models the emission lines arise from a continuous outflow , whereas in others they arise from orbiting gas clouds . Directly imaging such regions has not hitherto been possible because of their small angular size (less than 10 arcseconds ). Here we report a spatial offset (with a spatial resolution of 10 arcseconds, or about 0.03 parsecs for a distance of 550 million parsecs) between the red and blue photo-centres of the broad Paschen-α line of the quasar 3C 273 perpendicular to the direction of its radio jet. This spatial offset corresponds to a gradient in the velocity of the gas and thus implies that the gas is orbiting the central supermassive black hole. The data are well fitted by a broad-line-region model of a thick disk of gravitationally bound material orbiting a black hole of 3 × 10 solar masses. We infer a disk radius of 150 light days; a radius of 100-400 light days was found previously using reverberation mapping . The rotation axis of the disk aligns in inclination and position angle with the radio jet. Our results support the methods that are often used to estimate the masses of accreting supermassive black holes and to study their evolution over cosmic time.