Abstract:
The X-ray emission in BL Lac objects is believed to be dominated by synchrotron emission from their relativistic jets.
However, when the jet emission is not strong, one could expect signatures of X-ray emission from inverse Compton scattering of
accretion disc photons by hot and energetic electrons in the corona. Moreover, the observed X-ray variability can also originate in the
disc, and get propagated and amplified by the jet.
Aims. Here, we present results on the BL Lac object Mrk 421 using the Nuclear Spectroscopic Telescope Array data acquired during
2017 when the source was in a moderate X-ray brightness state. For comparison with high jet activity state, we also considered one
epoch of data in April 2013 when the source was in a very high X-ray brightness state. Our aim is to explore the possibility of the
signature of accretion disc emission in the overall X-ray emission from Mrk 421 and also examine changes in accretion parameters
considering their contribution to spectral variations.
Methods. We divided each epoch of data into different segments in order to find small-scale variability. Data for all segments were
fitted using a simple power-law model. We also fitted the full epoch data using the two component advective flow (TCAF) model to
extract the accretion flow parameters. Furthermore, we estimated the X-ray flux coming from the different components of the flow
using the lowest normalisation method and analysed the relations between them. For consistency, we performed the spectral analysis
using models available in the literature.
Results. The simple power-law function does not fit the spectra well, and a cutoff needs to be added. The spectral fitting of the data
using the TCAF model shows that the data can be explained with a model where (a) the size of the dynamic corona at the base of the
jet is from ∼28 to 10 rs
, (b) the disc mass accretion rate is from 0.021 to 0.051 M˙
Edd, (c) the halo mass accretion rate is from 0.22 to
0.35 M˙
Edd, and (d) the viscosity parameter of the Keplerian accretion disc from 0.18 to 0.25. In the assumed model, the total flux, disc
and jet flux correlate with the radio flux observed during these epochs.
Conclusions. From the spectral analysis, we conclude that the spectra of all the epochs of Mrk 421 in 2017 are well described by the
accretion-disc-based TCAF model. The estimated disc and jet flux relations with radio flux show that accretion disc can contribute to
the observed X-ray emission, when X-ray data (that cover a small portion of the broad band spectral energy distribution of Mrk 421)
are considered in isolation. However, the present disc-based models are disfavoured with respect to the relativistic jet models when
considering the X-ray data in conjunction with data at other wavelengths.