The orbital period of the recurrent nova V2487 Oph revealed

TL;DR

This study accurately determines the orbital period of the recurrent nova V2487 Oph, revealing it as one of the longest period cataclysmic variables, and provides insights into its binary system and accretion processes.

Contribution

First reliable measurement of V2487 Oph's orbital period using spectroscopic data, challenging previous estimates and suggesting a possible magnetic accretion mechanism.

Findings

Orbital period of 0.753 days (18.1 hours) determined.

Spectral features indicate a low-inclination accretion disc.

High-velocity emission observed during flares suggests magnetic accretion.

Abstract

We present the first reliable determination of the orbital period of the recurrent nova V2487 Oph (Nova Oph 1998). We derived a value of $0.753 \pm 0.016$ d ($18.1 \pm 0.4$ h) from the radial velocity curve of the intense He II $\lambda$4686 emission line as detected in time-series X-shooter spectra. The orbital period is significantly shorter than earlier claims, but it makes V2487 Oph one of the longest period cataclysmic variables known. The spectrum of V2487 Oph is prolific in broad Balmer absorptions that resemble a white dwarf spectrum. However, we show that they come from the accretion disc viewed at low inclination. Although highly speculative, the analysis of the radial velocity curves provides a binary mass ratio $q \approx 0.16$ and a donor star mass $M_2 \approx 0.21$ M$_\odot$, assuming the reported white dwarf mass $M_1 = 1.35$ M$_\odot$. A subgiant M-type star is tentatively suggested as the donor star. We were lucky to inadvertently take some of the spectra when V2487 Oph was in a flare state. During the flare, we detected high-velocity emission in the Balmer and He II $\lambda$4686 lines exceeding $-2000$ km s$^{-1}$ at close to orbital phase 0.4. Receding emission up to $1200$ km s$^{-1}$ at about phase 0.3 is also observed. The similarities with the magnetic cataclysmic variables may point to magnetic accretion on to the white dwarf during the repeating flares.