# Chandra Spectral and Timing Analysis of Sgr A*'s Brightest X-ray Flares

**Authors:** Daryl Haggard (McGill/MSI), Melania Nynka (MIT Kavli/McGill/MSI),, Brayden Mon (McGill/MSI), Noelia de la Cruz Hernandez (McGill/MSI), Michael, Nowak (Wash U), Craig Heinke (U Alberta), Joseph Neilsen (Villanova), Jason, Dexter (Max-Planck/JILA/U Colorado), P. Chris Fragile (Charleston), Fred, Baganoff (MIT Kavli), Geoffrey C. Bower (ASIAA), Lia R. Corrales (U, Michigan), Francesco Coti Zelati (CSIC/IEEC), Nathalie Degenaar (U, Amsterdam), Sera Markoff (U Amsterdam/GRAPPA), Mark R. Morris (UCLA),, Gabriele Ponti (INAF-OA-Brera/Max-Planck), Nanda Rea (CSIC/IEEC), Joern Wilms, (U Erlangen-Nuremberg), Farhad Yusef-Zadeh (Northwestern U/CIERA)

arXiv: 1908.01781 · 2019-12-05

## TL;DR

This study analyzes the brightest X-ray flares from Sagittarius A* using Chandra data, revealing their spectral and temporal properties, and finds no significant short-term variability or periodic signals, aiding understanding of the emission mechanisms.

## Contribution

It provides detailed spectral and timing analysis of the brightest Sgr A* flares, demonstrating their similarity to fainter flares and clarifying the nature of short-term variability.

## Key findings

- Bright flares have durations of 2-3 hours with rapid rise and decay.
- Flares are spectrally harder than quiescent emission, consistent with previous observations.
- No significant periodic or quasi-periodic variability detected in the flares.

## Abstract

We analyze the two brightest Chandra X-ray flares detected from Sagittarius A*, with peak luminosities more than 600 x and 245 x greater than the quiescent X-ray emission. The brightest flare has a distinctive double-peaked morphology --- it lasts 5.7 ksec ($\sim 2$ hours), with a rapid rise time of 1500 sec and a decay time of 2500 sec. The second flare lasts 3.4 ksec, with rise and decay times of 1700 sec and 1400 sec. These luminous flares are significantly harder than quiescence: the first has a power law spectral index $\Gamma = 2.06\pm 0.14$ and the second has $\Gamma = 2.03\pm 0.27$, compared to $\Gamma = 3.0\pm0.2$ for the quiescent accretion flow. These spectral indices (as well as the flare hardness ratios) are consistent with previously-detected Sgr A* flares, suggesting that bright and faint flares arise from similar physical processes. Leveraging the brightest flare's long duration and high signal-to-noise, we search for intraflare variability and detect excess X-ray power at a frequency of $\nu \approx 3$ mHz, but show that it is an instrumental artifact and not of astrophysical origin. We find no other evidence (at the 95% confidence level) for periodic or quasi-periodic variability in either flares' time series. We also search for non-periodic excess power but do not find compelling evidence in the power spectrum. Bright flares like these remain our most promising avenue for identifying Sgr A*'s short timescale variability in the X-ray, which may probe the characteristic size scale for the X-ray emission region.

## Full text

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## Figures

31 figures with captions in the complete paper: https://tomesphere.com/paper/1908.01781/full.md

## References

93 references — full list in the complete paper: https://tomesphere.com/paper/1908.01781/full.md

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Source: https://tomesphere.com/paper/1908.01781