A year-long AGILE observation of Cygnus X-1 in hard spectral state

TL;DR

This study monitored Cygnus X-1 in its hard spectral state over a year, analyzing its variability in X-ray and gamma-ray bands, finding erratic X-ray fluctuations and setting upper limits on gamma-ray emission, with implications for emission models.

Contribution

First long-term AGILE observation of Cygnus X-1 in hard state, applying advanced timing analysis and setting gamma-ray flux upper limits to constrain emission models.

Findings

X-ray flux shows erratic fluctuations with factor of two variations.

X-ray emission exhibits antipersistence, indicating negative feedback.

No significant gamma-ray emission detected, upper limit set at 5×10⁻⁸ ph cm⁻² s⁻¹.

Abstract

We present the observation of Cyg X-1 in hard spectral state performed during the AGILE Science Verification Phase and Observing Cycle 1 in hard X-rays (with SuperAGILE) and gamma rays (with the GRID) and lasting for about 160 days with a live time of $\sim 6$ Ms. We investigate the variability of Cyg X-1 in hard X-rays at different timescales, from $\sim 300$ s up to one day, and we apply different tools of timing analysis, such as the autocorrelation function, the first order structure function and the Lomb-Scargle periodogram, to our data (from SuperAGILE) and to the simultaneous data in soft X-rays (from RXTE/ASM). We conclude our investigation with a search for emission in the energy range above 100 MeV with the maximum likelihood technique. In the hard X-ray band the flux of Cyg X-1 shows its typical erratic fluctuations at all timescales with variations of about a factor of two that do not affect significantly the shape of the energy spectrum. From the first order structure function we find that the X-ray emission of Cyg X-1 is characterized by \textit{antipersistence}, indication of a negative feedback mechanism at work. In the gamma ray data a statistically significant point-like source at the position of Cyg X-1 is not found and the upper limit on the flux is $\mathrm{5 \times 10^{-8} \; ph \; cm^{-2} \; s^{-1}}$, over the whole observation (160 days). Finally we compare our upper limit in gamma rays with the expectation of various models of the Cyg X-1 emission, of both hadronic and leptonic origin, in the GeV -- TeV band. The time history of Cyg X-1 in the hard X-ray band over 13 months (not continuous) is shown. Different tools of analysis do not provide fully converging results of the characteristic timescales in the system, suggesting that the timescales found in the structure function are not intrinsic to the physics of the source.