A Systematic Search for Outbursting AM CVn Systems with the Zwicky Transient Facility

Roestel, Jan van; Creter, Leah; Kupfer, Thomas; Szkody, Paula; Fuller, Jim; Green, Matthew; Rich, R. Michael; Sepikas, J.; Burdge, Kevin B.; Caiazzo, Ilaria; Mróz, P.; Prince, Thomas A.; Duev, Dmitry A.; Graham, M. J.; Shupe, D. L.; Laher, Russ R.; Mahabal, A.; Masci, Frank J.

doi:10.3847/1538-3881/ac0622

Cited by 21 publications

(16 citation statements)

References 80 publications

(116 reference statements)

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“…This source was found as an outbursting source in ZTF by Szkody et al (2020), and later confirmed via spectroscopy to be an AM CVn by van Roestel et al (2021), who also looked at the outburts properties using ZTF data. Here, we report the observations with TESS.…”

Section: Ztf18abihypgmentioning

confidence: 78%

“…Both outbursts show similar profiles and duration of the order of one day. van Roestel et al (2021) report for this source a high frequency of outbursts, but during the two contiguous sectors of observation by TESS ( 54 d) we only see one outburst, meaning that for this source the recurrence time for normal outburst is larger than 50 d. The cadence of both sectors was of 30-min, meaning that we could not perform any periodicity search on the outburst to look for possible superhumps or confirm the orbital period. Based on the SO recurrence time, van Roestel et al ( 2021) predict a period of ∼31.2 min, this would imply a long recurrence time for the SO (Levitan et al 2015), and explains why we did not detect any SO in the two contiguous sectors.…”

Section: Ztf18abihypgmentioning

confidence: 88%

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TACOS: TESS AM CVn Outbursts Survey

Marcano

Sandoval

Maccarone

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Using TESS we are doing a systematic study of outbursting AM CVn systems to place some limits on the current outbursts models. We present the TESS light curve (LC) for 9 AM CVns showing both superoutbursts (SOs) and normal outbursts (NOs). The continuous coverage of the outbursts with TESS allows us to place stringent limits on the duration and structures of the SOs and the NOs. We present evidence that in at least some of the systems enhanced mass transfer (EMT) has to be taken into account to explain the observed LC of the SOs and rebrighthening phase after the SOs. For others, the colour evolution from simultaneous observations in g and r with ZTF differs from previously reported colour evolution of longer period AM CVns where EMT is responsible for the SO. We also find that due to the lack of sufficiently high cadence coverage the duration of many systems might have been overestimated in previous ground-based surveys. We report the SO duration for 6 AM CVns. We also found that precursors are a common feature of SOs in AM CVns and are seen in the LC of 5 of the 6 reported SOs. Finally the 10-minute and 2-minute cadence LCs from TESS also allowed us to find two new candidate orbital periods of AM CVns, both of which are in reasonably good agreement with the predictions for their periods based on their past outburst histories.

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Section: Ztf18abihypgmentioning

confidence: 78%

Section: Ztf18abihypgmentioning

confidence: 88%

TACOS: TESS AM CVn Outbursts Survey

Marcano

Sandoval

Maccarone

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…The Zwicky Transient Facility (ZTF; Kulkarni 2018) has been used prolifically in contemporary transient detection and characterization efforts. Astrophysical transients observed and/ or discovered by ZTF include: tidal disruption events (e.g., van Velzen et al 2021), candidate electromagnetic counterparts to gravitational wave events (e.g., Graham et al 2020), type Ia supernovae (e.g., Yao et al 2019;Bulla et al 2020;Miller et al 2020), dwarf novae (e.g., Soraisam et al 2021), cataclysmic variables (e.g., Szkody et al 2020), AM CvN systems (van Roestel et al 2021a), general stellar variables (e.g., Roulston et al 2021;van Roestel et al 2021b), active galactic nuclei (e.g., Frederick et al 2019;Ward et al 2021), and solar system bodies such as comets and asteroids (e.g., Ye et al 2020bYe et al , 2020a.…”

Section: Introductionmentioning

confidence: 99%

A Zwicky Transient Facility Look at Optical Variability of Young Stellar Objects in the North America and Pelican Nebulae Complex

Hillenbrand¹,

Kiker²,

Gee³

et al. 2022

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We present a study of 323 photometrically variable young stellar objects that are likely members of the North America and Pelican nebulae star-forming region. To do so, we utilize over two years of data in the g and r photometric bands from the Zwicky Transient Facility. We first investigate periodic variability, finding 46 objects (∼15% of the sample) with significant periods that phase well and can be attributed to stellar rotation. We then use the quasiperiodicity (Q) and flux asymmetry (M) variability metrics to assign morphological classifications to the remaining aperiodic light curves. Another ∼39% of the variable star sample beyond the periodic (low Q) sources are also flux-symmetric, but with a quasiperiodic (moderate Q) or stochastic (high Q) nature. Concerning flux-asymmetric sources, our analysis reveals ∼14% bursters (high negative M) and ∼29% dippers (high positive M). We also investigate the relationship between variability slopes in the g versus g − r color–magnitude diagram, and the light-curve morphological classes. Burster-type objects have shallow slopes, while dipper-type variables tend to have higher slopes that are consistent with extinction-driven variability. Our work is one of the earliest applications of the Q and M metrics to ground-based data. We therefore contrast the Q values of high-cadence and high-precision space-based data, for which these metrics were designed, with Q determinations resulting from degraded space-based light curves that have the cadence and photometric precision characteristic of ground-based data.

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“…Among the ∼1000 WDs observed by the Kepler K2 mission (Howell et al 2014 ), only one new DWD was disco v ered (Hallakoun et al 2016 ;van Sluijs & Van Eylen 2018 , along with one known DWD). The Zwicky Transient Facility (ZTF; Bellm et al 2019 ;Graham et al 2019 ;Masci et al 2019 ), which has begun operating in 2018, shows promising results, with already ∼10 newly disco v ered ultra-compact DWDs (Burdge et al 2019(Burdge et al , 2020aCoughlin et al 2020 ;Keller et al 2022 ; and see also van Roestel et al 2021 for interacting DWDs). In the near future, large all-sky surv e ys such as Gaia (Gaia Collaboration 2016, 2018 and the Vera Rubin Observatory (LSST Science Collaboration 2009 ) have the potential to deliver up to a few hundred and a few thousand of ne w eclipsing DWDs, respecti vely (Eyer et al 2012 ;Korol et al 2017 ).…”

Section: The Search For Dwdsmentioning

confidence: 99%

Observationally driven Galactic double white dwarf population for LISA

Korol

Hallakoun

Toonen

et al. 2022

Monthly Notices of the Royal Astronomical Society

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Realistic models of the Galactic double white dwarf (DWD) population are crucial for testing and quantitatively defining the science objectives of the Laser Interferometer Space Antenna (LISA), a future European Space Agency’s gravitational-wave observatory. In addition to numerous individually detectable DWDs, LISA will also detect an unresolved confusion foreground produced by the underlying Galactic population, which will affect the detectability of all LISA sources at frequencies below a few mHz. So far, the modelling of the DWD population for LISA has been based on binary population synthesis (BPS) techniques. The aim of this study is to construct an observationally-driven population. To achieve this, we employ a model developed by Maoz, Hallakoun & Badenes (2018) for the statistical analysis of the local DWD population using two complementary large, multi-epoch, spectroscopic samples: the Sloan Digital Sky Survey (SDSS), and the Supernova Ia Progenitor surveY (SPY). We calculate the number of LISA-detectable DWDs and the Galactic confusion foreground, based on their assumptions and results. We find that the observationally-driven estimates yield 1) 2 − 5 times more individually detectable DWDs than various BPS forecasts, and 2) a significantly different shape of the DWD confusion foreground. Both results have important implications for the LISA mission. A comparison between several variations to our underlying assumptions shows that our observationally-driven model is robust, and that the uncertainty on the total number of LISA-detectable DWDs is in the order of 20 per cent.

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A Systematic Search for Outbursting AM CVn Systems with the Zwicky Transient Facility

Cited by 21 publications

References 80 publications

TACOS: TESS AM CVn Outbursts Survey

TACOS: TESS AM CVn Outbursts Survey

A Zwicky Transient Facility Look at Optical Variability of Young Stellar Objects in the North America and Pelican Nebulae Complex

Observationally driven Galactic double white dwarf population for LISA

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