# The relation between outburst rate and orbital period in low-mass X-ray   binary transients

**Authors:** Jie Lin, Zhen Yan, Zhanwen Han, Wenfei Yu

arXiv: 1901.00239 · 2019-01-23

## TL;DR

This study analyzes the outburst rates of low-mass X-ray binary transients, revealing a correlation with orbital period and suggesting mass transfer mechanisms influence outburst behavior, with implications for binary evolution.

## Contribution

It identifies a critical orbital period and links outburst rates to donor star evolution, providing new insights into the mass transfer processes in LMXBTs.

## Key findings

- Short-period systems (<12 hr) show fewer outbursts.
- A negative correlation exists between outburst rate and orbital period.
- The critical orbital period is approximately 12.4 hours.

## Abstract

We have investigated the outburst properties of low-mass X-ray binary transients (LMXBTs) based on a comprehensive study of the outbursts observed in the past few decades. The outburst rates were estimated based on the X-ray monitoring data from Swift/BAT, RXTE/ASM and MAXI, and previous reports in the literature. We found that almost all LMXBTs with the orbital period below $\sim$12 hr showed only one outburst in these observations. There are systematic difference in the outburst rate between long-period ($P_{\rm orb} \gtrsim$ 12 hr) and short-period ($P_{\rm orb} \lesssim$ 12 hr) systems. We infer that mass transfer rate is responsible for the systematic difference, since the disk instability model (DIM) suggested that the mass transfer rate is a key factor affecting the quiescence time. The difference in outburst rate between long-period and short-period LMXBTs is probably due to the different mass transfer mechanism at different evolutionary stages of the donors. Based on the evolutionary tracks of single stars, we derived the critical orbital period for X-ray binaries that harbor a subgiant donor in various metallicity. The critical orbital period ($P_{\rm orb,crit}=$12.4 hr) is consistent with the above orbital period boundary obtained from the statistics of outburst rates. Furthermore, we found a negative correlation between the outburst rate and the orbital period in the samples for which the luminosity class of the donor star is III/IV. The best-fitting power-law index for the black hole subsamples is roughly consistent with the theoretical prediction for those systems with a donor star evolved off the main sequence.

## Full text

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## Figures

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## References

173 references — full list in the complete paper: https://tomesphere.com/paper/1901.00239/full.md

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Source: https://tomesphere.com/paper/1901.00239