BK Lyncis: The Oldest Old Nova?... And a Bellwether for Cataclysmic-Variable Evolution

TL;DR

This 20-year study of BK Lyncis suggests it is a postnova remnant transitioning into a dwarf nova, providing insights into cataclysmic variable evolution and the impact of nova eruptions on their long-term behavior.

Contribution

It proposes that the second parameter in CV evolution is the time since the last nova, explaining various observed phenomena in short-period cataclysmic variables.

Findings

BK Lyn's light curve resembles a dwarf nova from 2005 onward.

The star's behavior supports the hypothesis of a postnova cooling process.

ER UMa stars may be remnants of recent novae, explaining their rarity.

Abstract

We summarize the results of a 20-year campaign to study the light curves of BK Lyncis, a nova-like star strangely located below the 2-3 hour orbital period gap in the family of cataclysmic variables. Two apparent "superhumps" dominate the nightly light curves - with periods 4.6% longer, and 3.0% shorter, than P_orb. The first appears to be associated with the star's brighter states (V~14), while the second appears to be present throughout and becomes very dominant in the low state (V~15.7). Starting in the year 2005, the star's light curve became indistinguishable from that of a dwarf nova - in particular, that of the ER UMa subclass. Reviewing all the star's oddities, we speculate: (a) BK Lyn is the remnant of the probable nova on 30 December 101, and (b) it has been fading ever since, but has taken ~2000 years for the accretion rate to drop sufficiently to permit dwarf-nova eruptions. If such behavior is common, it can explain other puzzles of CV evolution. One: why the ER UMa class even exists (because all members can be remnants of recent novae). Two: why ER UMa stars and short-period novalikes are rare (because their lifetimes, which are essentially cooling times, are short). Three: why short-period novae all decline to luminosity states far above their true quiescence (because they're just getting started in their postnova cooling). Four: why the orbital periods, accretion rates, and white-dwarf temperatures of short-period CVs are somewhat too large to arise purely from the effects of gravitational radiation (because the unexpectedly long interval of enhanced postnova brightness boosts the mean mass-transfer rate). These are substantial rewards in return for one investment of hypothesis: that the second parameter in CV evolution, besides P_orb, is time since the last classical-nova eruption.