A comprehensive study of type I (thermonuclear) bursts in the new transient SRGA J144459.2$-$604207

TL;DR

This study analyzes 60 type I X-ray bursts from the transient pulsar SRGA J144459.2-604207, revealing burst properties, fuel composition, and distance, with implications for understanding thermonuclear burst mechanisms.

Contribution

It provides the first detailed analysis of type I bursts from SRGA J144459.2-604207, including spectral, compositional, and recurrence time measurements, expanding knowledge of this new transient.

Findings

Detected 60 type I X-ray bursts during outburst.

Estimated source distance as 10.0 kpc.

Observed burst recurrence time increases as accretion rate decreases.

Abstract

We report an analysis of Insight-HXMT observations of the newly discovered accreting millisecond pulsar SRGA J144459.2$-$604207. During the outburst, detected in 2024 February by SRG/ART-XC, the broadband persistent spectrum was well fitted by an absorbed Comptonization model. We detected 60 type I X-ray bursts in the Insight-HXMT medium energy (ME) data, and 37 were also detected with the low-energy (LE) telescope. By superimposing the Insight-HXMT/LE/ME/HE light curves of 37 bursts with similar profiles and intensities, we measured a deficit of X-rays in the $40-70$ keV energy band. By analyzing the time-resolved X-ray burst spectra, we determine the mean ratio of persistent to burst flux of $\alpha=71\pm7$. We estimate the average hydrogen mass fraction in the fuel at ignition, as $\bar{X} =0.342\pm0.033$, and constrain the burst fuel composition as $X_0\leq0.4$. We found that 14 out of 60 X-ray bursts exhibited photospheric expansion, and thus we estimated the distance to the source as $10.0\pm0.71$ kpc. Combined with IXPE observations, the burst recurrence time increased from 1.55 to 8 hr as the local mass accretion rate decreased, which can be described as $\Delta T_{\rm rec}\sim \dot{m}^{-0.91\pm0.02}$.