Temporal evolution of long-timescale periodicities in ULX NGC 5408 X-1

TL;DR

This study analyzes the long-term X-ray periodicities of ULX NGC 5408 X-1, revealing stable and variable super-orbital signals likely caused by accretion disc precession, using wavelet analysis over 4.2 years.

Contribution

It provides the first detailed analysis of the temporal evolution of multiple long-timescale periodicities in NGC 5408 X-1 using wavelet techniques.

Findings

Detected three significant periodicities at 2.65, 115, and 189 days.

The 2.65-day period is stable over time.

The 189-day period shows a decreasing trend from 193 to 181 days.

Abstract

Context. NGC 5408 X-1 is one of the few ultraluminous X-ray sources with an extensive monitoring program in X-rays (a temporal baseline of 4.2 yr), making it one of the most suitable candidates to study the long-timescale quasi-periodic oscillations (QPOs). Aims. Previous timing analysis of the Swift data of NGC 5408 X-1 led to detection of multiple periodicities ranging from 2.6 d to 230 d. In this paper, we focus on the statistical significance and the temporal evolution of these periodicities. Methods. A time-series analysis technique in the time-frequency domain, the weighted wavelet Z-transform (WWZ), was employed to identify the periodicities and trace their variations with time. Results. Three periodic components were detected from the WWZ periodogram, corresponding to periods of 2.65$\pm$0.01 d, 115.4$\pm$14.4 d and 189.1$\pm$15.2 d. All three have statistical significance higher than 99.74%. The 2.65-d periodicity is quite stable in the majority of the light curve. The 115-d periodicity is the most prominent but appears variable. The 189-d periodicity is persistent across the whole time coverage. It shows a steadily decreasing trend from the beginning (193 d period) to the end (181 d period). Conclusions. The long-timescale periodicities in NGC 5408 X-1 are most likely of super-orbital origin, and are probably associated with the precession of a warped accretion disc. The disc may have been broken into two distinct planes with different precessing periods, i.e. the 189-d and 115-d periodicities corresponding to the outer and inner disc, respectively.