Observational stellar astrophysics
My research interests are mainly the late stages of binary evolution and LISA sources including white dwarf binaries, hot subdwarf binaries and pulsators and ultracompact AM CVn type binaries. I use time-domain data mainly from the Zwicky Transient Facility and perform crossmatches with other large-scale surveys to to discover and characterize rare events and populations of different stellar types. As part of my PhD thesis I studied the population of short period hot subdwarf binaries which are discussed as possible progenitors for AM CVn type binaries. I also conducted a detailed study of individual ultracompact AM CVn type systems to put constraints on the population as well as formation history of these unique systems.
Ultracompact hot subdwarf binaries
Hot subluminous B stars (sdBs) are core helium-burning stars with very thin hydrogen envelopes and masses around 0.5 Msol. A large fraction of sdBs reside in short period binaries with a low mass main sequence or white dwarf companion. For close binary sdBs common envelope ejection is the most probable formation channel. Evolutionary studies have shown that the orbital period of a hot subdwarf with a white dwarf companion has to be smaller than about 120 min on exit from the last common enveope phase to still have an sdB that is core or shell helium burning when it fills its Roche lobe assuming that the further orbital period evolution is set by the emission of gravitational waves only. In the subsequent evolution, if helium burning is still ongoing, the sdB fills its Roche lobe first and starts to transfer He-rich material onto the white dwarf which could result in a detonation of the white dwarf or formation a stable helium accreting AM CVn type system.
AM CVn type binaries
AM CVn systems are rare, ultracompact binaries consisting of a white dwarf primary and a (semi- )degenerate secondary. Only about 60 AM CVn systems are known. They show orbital periods in a range of 5.4 - 65 min. As these systems evolve from a short orbital period, their mass transfer rate decreases by several orders of magnitude as the orbit widens and the orbital period increases. As ultracompact binaries, they are one of the strongest and most abundant sources of gravitational wave radiation in the LISA regime and some of the them will be verification binaries at launch. The exact formation channel of AM CVn systems is still unknown and three scenarios have been proposed. In the first, two old and completely degenerate white dwarfs start mass transfer, in the second the mass donor is a semi-degenerate helium star and in the third the donor is a well-evolved main-sequence star.
Large-amplitude Radial-mode hot subdwarf pulsators (high-gravity BLAPs)
Hot subdwarf stars are known to pulsate with g-modes or p-modes. In all cases photometric amplitudes do not exceed a few percent. High-gravity BLAPs are a new type of pulsator which show typical periods for p-modes and spectroscopic properties of hot subdwarfs but pulsate with amplitudes >10 percent. Additionally they show large velocity, temperature and surface gravity variations over the pulsation cycle, typical for radial mode pulsators. Four canidates were discovered in data from the Zwicky Transient Facility.