Remarkable spectral variability on the spin period of the accreting white dwarf in V455 And

TL;DR

This study uses high-cadence spectroscopy with EMCCDs to analyze the spectral variability of the rapidly spinning white dwarf in V455 And, revealing complex emission line behavior linked to magnetic accretion processes.

Contribution

First high-cadence spectral study of V455 And revealing detailed emission line variability tied to its fast spin and magnetic accretion.

Findings

Detected a precise spin period of 67.619 seconds.

Observed complex emission line variations correlated with the white dwarf's spin.

Found a structureless accretion disc unlike typical intermediate polars.

Abstract

We present spin-resolved spectroscopy of the accreting white dwarf binary V455 And. With a suggested spin period of only 67s, it has one of the fastest spinning white dwarfs known. To study the spectral variability on the spin period of the white dwarf, we observed V455 And with 2s integration times, which is significantly shorter than the spin rate of the white dwarf. To achieve this cadence, we used the blue arm of the ISIS spectrograph at the 4.2-m William Herschel Telescope, equipped with an electron multiplying CCD (EMCCD). Strong coherent signals were detected in our time series, which lead to a robust determination of the spin period of the white dwarf (Pspin=67.619 +/- 0.002 s). Folding the spectra on the white dwarf spin period uncovered very complex emission line variations in Hgamma, He I 4472 and He II 4686. We attribute the observed spin phase dependence of the emission line shape to the presence of magnetically controlled accretion onto the white dwarf via accretion curtains, consistent with an intermediate polar type system. We are, however, not aware of any specific model that can quantitatively explain the complex velocity variations we detect in our observations. The orbital variations in the spectral lines indicate that the accretion disc of V455 And is rather structureless, contrary to the disc of the prototype of the intermediate polars, DQ Her. This work demonstrates the potential of electron multiplying CCDs to observe faint targets at high cadence, as readout noise would make such a study impossible with conventional CCDs.