# A Hubble Space Telescope Survey for Novae in M87. II. Snuffing out the   Maximum Magnitude - Rate of Decline Relation for Novae as a Non-Standard   Candle, and a Prediction of the Existence of Ultrafast Novae

**Authors:** Michael M. Shara, Trisha Doyle, Tod R. Lauer, David Zurek, Edward A., Baltz, Attay Kovetz, Juan P. Madrid, Joanna Mikolajewska, J.D. Neill, Dina, Prialnik, Doug L. Welch, and Ofer Yaron

arXiv: 1702.05788 · 2017-05-03

## TL;DR

This paper investigates the deviation of certain novae from the standard candle MMRD relation, explains the causes using simulations, and predicts the existence of ultrafast novae with very rapid decline times.

## Contribution

It identifies the physical reasons for faint, fast novae and predicts ultrafast novae with decline times as short as five hours, expanding understanding of nova diversity.

## Key findings

- Faint, fast novae comprise about 40% of eruptions in M87.
- These novae result from low-mass envelopes on massive white dwarfs.
- Ultrafast novae with decline times as short as five hours are predicted.

## Abstract

The extensive grid of numerical simulations of nova eruptions of Yaron et al.(2005) first predicted that some classical novae might deviate significantly from the Maximum Magnitude - Rate of Decline (MMRD) relation, which purports to characterise novae as standard candles. Kasliwal et al. (2011) have announced the observational detection of an apparently new class of faint, fast classical novae in the Andromeda galaxy. These objects deviate strongly from the MMRD relationship, exactly as predicted by Yaron et al. (2005). Shara et al. (2016) recently reported the first detections of faint, fast novae in M87. These previously overlooked objects are as common in the giant elliptical galaxy M87 as they are in the giant spiral M31; they comprise about 40% of all classical nova eruptions and greatly increase the observational scatter in the MMRD relation. We use the extensive grid of nova simulations of Yaron et al. (2005) to identify the underlying causes of the existence of faint, fast novae. These are systems which have accreted, and can thus eject, only very low mass envelopes, of order 10^-7 - 10^-8 Msun, on massive white dwarfs. Such binaries include, but are not limited to, the recurrent novae. These same models predict the existence of ultrafast novae which display decline times t2 as short as five hours. We outline a strategy for their future detection.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1702.05788/full.md

## References

54 references — full list in the complete paper: https://tomesphere.com/paper/1702.05788/full.md

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Source: https://tomesphere.com/paper/1702.05788