The Long-term Secular Mass Accretion Rate of the Recurrent Nova T Pyxidis*

Godon, Patrick; Sion, E. M.; Williams, Robert E.; Starrfield, S.

doi:10.3847/1538-4357/aacd0a

Cited by 15 publications

(11 citation statements)

References 75 publications

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“…Their white dwarf masses and accretion rates are, for T Pyx, 1.23 M ⊙ , 1.12 ×10 −7 M ⊙ /yr; for IM Nor, 1.21 M ⊙ , 4.8 ×10 −8 M ⊙ /yr; and for CI Aql, 1.21 M ⊙ , 1.12 ×10 −7 M ⊙ /yr. By comparison, Godon, et al (2018) derivedṀ ∼ 10 −7 M ⊙ /yr and M wd = 1.2M ⊙ for T Pyx, which is in good agreement. For CI Aql we derived 4 ×10 −8 M ⊙ /yr, which is nearly a factor of three smaller than Shara, et al (2015).…”

Section: Discussionsupporting

confidence: 62%

Hubble Space Telescope Far-UV Spectroscopy of the Short Orbital Period Recurrent Nova CI Aql: Implications for White Dwarf Mass Evolution

Sion

Wilson

Godon

et al. 2019

ApJ

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An HST COS Far UV spectrum (1170Å to 1800Å) was obtained for the short orbital period recurrent novae (T Pyxidis subclass), CI Aquilae. CI Aql is the only classical CV known to have two eclipses of sensible depth per orbit cycle and also have pre-and post-outburst light curves that are steady enough to allow estimates of mass and orbital period changes. Our FUV spectral analysis with model accretion disks and NLTE high gravity photospheres, together with the Gaia parallax, reveal CI Aql's FUV light is dominated by an optically thick accretion disk with an accretion rate of the order of 4 ×10 −8 M ⊙ /yr. Its database of light curves, radial velocity curves, and eclipse timings is among the best for any CV. Its orbit period (P ), dP/dt, and reference time are re-derived via simultaneous analysis of the three data types, giving a dimensionless post-outburst dP/dt of −2.49 ± 0.95 × 10 −10 . Lack of information on loss of orbital to rotational angular momentum leads to some uncertainty in the translation of dP/dt to white dwarf mass change rate, dM 1 /dt, but within the modest range of +4.8 × 10 −8 to +7.8 × 10 −8 M ⊙ /yr. The estimated white dwarf mass change through outburst for CI Aql, based on simple differencing of its pre-and post outburst orbit period, is unchanged from the previously published +5.3 × 10 −6 M ⊙ . At the WD's estimated mass increase rate, it will terminate as a Type Ia supernova within 10 million years.

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Section: Discussionsupporting

confidence: 62%

Hubble Space Telescope Far-UV Spectroscopy of the Short Orbital Period Recurrent Nova CI Aql: Implications for White Dwarf Mass Evolution

Sion

Wilson

Godon

et al. 2019

ApJ

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“…At the intersection of the solid and dotted lines, is just enough to lift itself out through L1 using the accretion luminosity = / ( and are the white dwarf's mass and radius, respectively). We find that the self-sustaining rate is ∼ 10 −7 M ⊙ yr −1 (equivalently ∼ 10 36 erg s −1 ), providing a possible explanation for the puzzling high accretion rates of the recurrent novae T Pyx and IM Nor during quiescence (Patterson et al 2017(Patterson et al , 2020Godon et al 2018). Knigge et al (2000) proposed a different self-sustaining mechanism for T Pyx: an irradiation-driven wind carries away angular momentum from the binary, driving the companion to overflow its Roche lobe.…”

Section: Bootstrapping (Self-sustaining Accretion)mentioning

confidence: 73%

“…We find that under certain conditions, the decline halts and the mass transfer becomes self-sustaining: the white dwarf's accretion luminosity is enough to drive the accreted mass through the irradiated companion's Roche lobe. This 'bootstrapping' state may explain the high quiescent accretion rates (∼ 10 −7 M ⊙ yr −1 ) recently observed for the recurrent novae T Pyxidis (T Pyx) and IM Normae (IM Nor) (Patterson et al 2017(Patterson et al , 2020Godon et al 2018). If the self-sustaining rate is sufficiently high, the white dwarf can burn accreted hydrogen stably (Nomoto et al 2007;Shen & Bildsten 2007;Wolf et al 2013), potentially explaining long-lived supersoft X-ray sources with short orbital periods like RX J0537.7-7034 and 1E 0035.4-7230 as well (Kahabka & van den Heuvel 1997;King et al 2001).…”

Section: Introductionmentioning

confidence: 85%

Novae heat their food: mass transfer by irradiation

Ginzburg,

Quataert

2021

Preprint

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A nova eruption irradiates and heats the donor star in a cataclysmic variable to high temperatures irr , causing its outer layers to expand and overflow the Roche lobe. We calculate the donor's heating and expansion both analytically and numerically and find that irradiation drives enhanced mass transfer from the donor at a rate ∝ 5/3 irr , which reaches ∼ 10 −6 M ⊙ yr −1 at the peak of the eruption -about a thousand times faster than during quiescence. As the nova subsides and the white dwarf cools down, drops to lower values. We find that under certain circumstances, the decline halts and the mass transfer persists at a self-sustaining rate of ∼ 10 −7 M ⊙ yr −1 for up to ∼ 10 3 yr after the eruption. At this rate, irradiation by the white dwarf's accretion luminosity is sufficient to drive the mass transfer on its own. The self-sustaining rate is close to the white dwarf's stable burning limit, such that this bootstrapping mechanism can simultaneously explain two classes of puzzling binary systems: recurrent novae with orbital periods ≈ 2 h (T Pyxidis and IM Normae) and long-lived supersoft X-ray sources with periods ≈ 4 h (RX J0537.7-7034 and 1E 0035.4-7230). Whether or not a system reaches the self-sustaining state is sensitive to the donor's chromosphere structure, as well as to the orbital period change during nova eruptions.

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“…The majority of Galactic RNe follow the picture painted above, with 30% hosting a sub-giant donor and 50% with a red giant donor [10]. Yet two systems, T Pyxidis and IM Normae -the "recurrent unusual novae" -seemingly with main sequence donors, lower mass WDs, and short orbital periods, may buck this trend (for a non-complete selection of discussion articles about these unusual RNe see [32,33,34]). Figure 1 presents a colour-magnitude diagram (based on [10]) that illustrates how near-IR quiescent photometry is used to determine the donor type in a nova system.…”

Section: Recurrent Novae and The Mmrdmentioning

confidence: 87%

Accrete, Accrete, Accrete… Bang! (and repeat): The remarkable Recurrent Novae

Darnley¹

2021

Proceedings of the Golden Age of Cataclysmic Variables and Related Objects v — PoS(GOLDEN2019)

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All novae recur, but only a handful have been observed in eruption more than once. These systems, the recurrent novae (RNe), are among the most extreme examples of novae. RNe have long been thought of as potential type Ia supernova progenitors, and their claim to this 'accolade' has recently been strengthened. In this short review RNe will be presented within the framework of the maximum magnitude-rate of decline (MMRD) phase-space. Recent work integrating Heflashes into nova models, and the subsequent growth of the white dwarf, will be explored. This review also presents an overview of the Galactic and extragalactic populations of RNe, including the newly identified 'rapid recurrent nova' subset-those with recurrence periods of ten years, or less. The most exciting nova system yet discovered-M31N 2008-12a, with its annual eruptions and vast nova super-remnant, is introduced. Throughout, open questions regarding RNe, and some of the expected challenges and opportunities that the near future will bring are addressed.

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The Long-term Secular Mass Accretion Rate of the Recurrent Nova T Pyxidis*

Cited by 15 publications

References 75 publications

Hubble Space Telescope Far-UV Spectroscopy of the Short Orbital Period Recurrent Nova CI Aql: Implications for White Dwarf Mass Evolution

Hubble Space Telescope Far-UV Spectroscopy of the Short Orbital Period Recurrent Nova CI Aql: Implications for White Dwarf Mass Evolution

Novae heat their food: mass transfer by irradiation

Accrete, Accrete, Accrete… Bang! (and repeat): The remarkable Recurrent Novae

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