# FUSE Spectroscopic Analysis of the Slowest Symbiotic Nova AG Peg During   Quiescence

**Authors:** Edward M. Sion, Patrick Godon, Joanna Mikolajewska, Marcus Katynski

arXiv: 1902.10002 · 2019-04-17

## TL;DR

This study analyzes the far ultraviolet spectrum of the symbiotic nova AG Peg during quiescence, revealing a hot white dwarf with a temperature of 150,000 K and discussing the spectral contributions of the white dwarf and potential accretion disk.

## Contribution

First detailed FUV spectral modeling of AG Peg during quiescence, identifying a hot white dwarf as the dominant source of UV flux and evaluating accretion disk presence.

## Key findings

- White dwarf temperature ~150,000 K
- White dwarf radius ~0.06 Rsun at 800 pc
- Accretion disk models less favored than WD photosphere

## Abstract

We present a far ultraviolet spectroscopic analysis of the slowest known symbiotic nova AG Peg (M3/4III giant + hot white dwarf; P = 818.4 days) which underwent a nova explosion in 1850 followed by a very slow decline that did not end until 1996, marking the beginning of quiescence. The 19 years of quiescence ended in June 2015, when AG Peg exhibited a Z And-type outburst with an optical amplitude of 1.5 magnitudes.   We have carried out accretion disk and WD photosphere synthetic spectral modeling of a Far Ultraviolet Spectroscopic Explorer (FUSE) spectrum obtained on June 5.618, 2003 during the quiescence interval 12 years before the 2015 outburst. The spectrum is heavily affected by ISM absorption as well as strong emission lines. We de-reddened the FUSE fluxes assuming E(B-V) = 0.10, which is the maximum galactic reddening in the direction of AG Peg. We discuss our adoption of the pre-Gaia distance over the Gaia parallax. For a range of white dwarf surface gravities and surface temperatures we find that the best-fitting photosphere is a hot WD with a temperature T = 150,000 K, and a low gravity log(g)~6.0-6.5. For a distance of 800 pc, the scaled WD radius is about 0.06 Rsun, giving log(g) = 6.67 for a 0.65 Msun WD mass. The Luminosity we obtain from this model is 1729 Lsun. The hot photosphere models provide better fits than the accretion disk models which have FUV flux deficits toward the shorter wavelengths of FUSE, down to the Lyman Limit. Given the uncertainty of the nature of a true symbiotic accretion disk, and, while a very hot low gravity degenerate star dominates the FUV flux, the presence of a steady-state (standard) accretion disk cannot be summarily ruled out.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1902.10002/full.md

## References

45 references — full list in the complete paper: https://tomesphere.com/paper/1902.10002/full.md

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Source: https://tomesphere.com/paper/1902.10002