Abstract:
We present AstroSat soft X-ray, near-UV (NUV), and far-UV (FUV) observations of a blazar, OJ 287, carried out in 2017, 2018,
and 2020. The simultaneous observations with NuSTAR in 2017 provide a broad-band look encompassing NUV, FUV, soft, and
hard X-rays. Captured in three different broad-band spectral states in three observations, the X-ray spectrum is found to be the
hardest during 2018, while the high-energy-end of the simultaneous optical-FUV spectrum shows a steepening that is modelled
with a broken power-law spectrum. The spectral energy distribution (SED) in 2017 shows a relatively flatter optical-FUV and
soft X-ray spectra, implying an additional emission component. The 2020 optical-FUV spectrum is harder than in 2017 and
2018, with an extremely soft X-ray spectrum and a hardening above ∼1 GeV, similar to the SEDs of High-energy-peaked
BL Lac objects (HBL), thereby establishing that this additional emission component has HBL-like properties. The AstroSat
multiwavelength observationstrace the spectral evolution from the end-phase of the HBL component in 2017 to its disappearance
in 2018 followed by its revival in 2020. A single zone leptonic model reproduces the 2018 broad-band spectrum, while the 2017
and 2020 SEDs require an additional HBL-like emitting zone. The spectral evolution of the high-energy-end of optical-UV
spectrum, revealed by the FUV observations in 2017 and 2018, strongly suggests that X-ray spectral changes in the normal
broad-band spectral state of OJ 287 are primarily due to the evolution of the optical-UV synchrotron spectrum.
