Voracious vortexes in cataclysmic variables. A multi-epoch tomographic study of HT Cassiopeia

TL;DR

This multi-epoch study of HT Cassiopeia reveals a large, complex accretion disc with distinct emission regions, challenging previous radius measurements and suggesting irradiation effects on the disc's outer regions.

Contribution

The paper provides detailed Doppler tomograms of HT Cas across multiple epochs, uncovering complex emission structures and a persistently large disc near the tidal truncation radius, contrasting earlier findings.

Findings

Disc radius is close to the tidal truncation limit.

Multiple emission regions including hot spots and spiral structures.

Outer disc regions have low density, allowing near-free gas stream flow.

Abstract

We present multi-epoch, time-resolved optical spectroscopic observations of the dwarf nova HT Cas, obtained during 1986, 1992, 1995 and 2005 with the aim to study the properties of emission structures in the system. We determined that the accretion disc radius, measured from the double-peaked emission line profiles, is persistently large and lies within the range of 0.45-0.52a, where a is the binary separation. This is close to the tidal truncation radius r_max=0.52a. This result contradicts with previous radius measurements. An extensive set of Doppler maps has revealed a very complex emission structure of the accretion disc. Apart from a ring of disc emission, the tomograms display at least three areas of enhanced emission: the hot spot from the area of interaction between the gas stream and the disc, which is superposed on the elongated spiral structure, and the extended bright region on the leading side of the disc, opposite to the location of the hot spot. The position of the hot spot in all the emission lines is consistent with the trajectory of the gas stream. However, the peaks of emission are located in the range of distances 0.22-0.30a, which are much closer to the white dwarf than the disc edge. This suggests that the outer disc regions have a very low density, allowing the gas stream to flow almost freely before it starts to be seen as an emission source. We have found that the extended emission region in the leading side of the disc is always observed at the very edge of the large disc. Observations of other cataclysmic variables, which show a similar emission structure in their tomograms, confirm this conclusion. We propose that the leading side bright region is caused by irradiation of tidally thickened sectors of the outer disc by the white dwarf and/or hot inner disc regions.