Litcius/Paper detail

Velocity-resolved Reverberation Mapping of Changing-look AGN NGC 2617

Hai-Cheng Feng, H. T. Liu, J. M. Bai, Zi-Xu Yang, Chen Hu, Sha-Sha Li, Sen Yang, Kai-Xing Lu, Ming Xiao

2021The Astrophysical Journal33 citationsDOIOpen Access PDF

Abstract

Abstract NGC 2617 attracted a lot of attention after the detection of changes in its spectral type; the geometry and kinematics of the broad-line region (BLR) are still ambiguous. In this paper, we present the high cadence (∼2 days) reverberation mapping campaign of NGC 2617 from 2019 October to 2020 May undertaken at the Lijiang 2.4 m telescope. For the first time, the velocity-resolved reverberation signature of the object was successfully detected. Both H α and H β show an asymmetrical profile with a peak in the velocity-resolved time lags. For both of the lines, the lag of the line core is longer than those of the relevant wings, and the peak of the velocity-resolved lags is slightly blueshifted. These characteristics are not consistent with the theoretical prediction of the inflow, outflow or Keplerian disk model. Our observations give the time lags of H α , H β , H γ , and He i , with a ratio of τ H α : τ H β : τ H γ : τ He I = 1.27:1.00:0.89:0.20, which indicates a stratified structure in the BLR of the object. It is the first time that the lags of H α and He i are obtained. Assuming a virial factor of f = 5.5 for the dispersion width of the line, the masses of the black holes derived from H α and H β are and , respectively. Our observed results indicate the complexity of the BLR of NGC 2617.

Topics & Concepts

PhysicsReverberation mappingAstrophysicsReverberationOutflowVirial theoremVelocity dispersionKinematicsAccretion (finance)Dispersion (optics)Line (geometry)Accretion discLagAstronomyTime lagSuperluminal motionSpectral lineActive galactic nucleusCore (optical fiber)Computational physicsAccelerationBlack hole (networking)Arrival timeRedshiftLuminositySupersonic speedStellar, planetary, and galactic studiesAstrophysics and Star Formation StudiesAdaptive optics and wavefront sensing