On the vanishing orbital X-ray variability of the eclipsing binary millisecond pulsar 47 Tuc W

TL;DR

This study investigates the X-ray orbital variability of the redback millisecond pulsar 47 Tuc W across multiple epochs, revealing both instrumental and intrinsic factors affecting observed variability and modeling the system's properties.

Contribution

The paper provides a comprehensive analysis of X-ray variability in 47 Tuc W, combining multi-epoch observations with spectral modeling and stellar simulations to understand its orbital behavior and system parameters.

Findings

X-ray orbital variability persisted across epochs, indicating intrinsic system stability.

Instrument sensitivity and spectral components influence observed X-ray light-curves.

Modeling suggests a high-inclination, pulsar-heated system with a wind-dominated intrabinary shock.

Abstract

Redback millisecond pulsars (MSPs) typically show pronounced orbital variability in their X-ray emission due to our changing view of the intrabinary shock (IBS) between the pulsar wind and stellar wind from the companion. Some redbacks ("transitional" MSPs) have shown dramatic changes in their multiwavelength properties, indicating a transition from a radio pulsar state to an accretion-powered state. The redback MSP 47 Tuc W showed clear X-ray orbital variability in the Chandra ACIS-S observations in 2002, which were not detectable in the longer Chandra HRC-S observations in 2005-06, suggesting that it might have undergone a state transition. However, the Chandra observations of 47 Tuc in 2014-15 show similar X-ray orbital variability as in 2002. We explain the different X-ray light-curves from these epochs in terms of two components of the X-ray spectrum (soft X-rays from the pulsar, vs. harder X-rays from the IBS), and different sensitivities of the X-ray instruments observing in each epoch. However, when we use our best-fit spectra with HRC response files to model the HRC light-curve, we expect a more significant and shorter dip than that observed in the 2005-06 Chandra data. This suggests an intrinsic change in the IBS of the system. We use the ICARUS stellar modelling software, including calculations of heating by an IBS, to model the X-ray, optical, and UV light-curves of 47 Tuc W. Our best-fitting parameters point towards a high-inclination system (i~60 deg), which is primarily heated by the pulsar radiation, with an IBS dominated by the companion wind momentum.