C. Sáez-Carvajal, N. Vogt, M. Zorotovic, J. García-Veas, G. Aravena-Rojas, L. Dumond, F. Figueroa-Tapia, Y. López-Bonilla, A. Rodríguez-Jiménez, I. Vega-Manubens, B. Grawe
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We determine new orbital periods for 75 DNe and improve ephemerides for 27 more (three of which change significantly), contributing 9.4% of the known DNe periods of between 0.05 and 2.0 days, and doubling the number of known periods exceeding 0.44 days. Their phase-folded light curves are presented and arranged by orbital period, illustrating the transition from short-period systems, dominated by radiation from the accretion disc and the hot spot, to longer-period DNe, where the Roche-lobe-filling secondary star is the primary visual flux source. This transition – which occurs around the well-known period gap (between ∼2 and 3 hours) – is expected, as DNe with larger orbital periods typically harbour more massive donors, which contribute to the visible flux. However, this transition is not abrupt. Within the same range of periods, we observe systems dominated by ellipsoidal variations, where the companion star is clearly visible, as well as others dominated by the disc and the hot spot. The presence of some DNe with ellipsoidal variations near the lower edge of the period gap is striking, as the companions in these systems are expected to be cool low-mass M-dwarfs not visible in the light curve. 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引用次数: 0
摘要
大灾变的轨道周期是研究这些双星系统的结构和物理以及了解其演化的关键参数。我们利用盖亚对处于静止状态的矮新星(DNe)的光度测量数据--这些数据已经存在多年--来确定新的轨道周期,并改进或修改以前提出的周期值。我们采用了两种方法来选择高倾角目标,一种是日食目标,另一种是具有椭圆形变化的目标。我们为 75 个 DNe 确定了新的轨道周期,并改进了另外 27 个 DNe 的星历表(其中 3 个发生了重大变化),使已知 DNe 周期的 9.4% 介于 0.05 天和 2.0 天之间,并使超过 0.44 天的已知周期数量翻了一番。我们按轨道周期展示和排列了它们的相位折叠光曲线,说明了从以吸积盘和热点辐射为主的短周期系统到以填充罗氏室的次星为主要视觉通量源的长周期 DNe 的过渡。这种过渡发生在众所周知的周期间隙(2~3 小时之间)附近,这在意料之中,因为轨道周期较大的 DNe 通常会有更大质量的供体,从而为可见光通量做出贡献。然而,这种转变并不突然。在相同的周期范围内,我们观测到了以椭球变异为主的系统(伴星清晰可见),以及其他以圆盘和热点为主的系统。在周期间隙的下边缘附近存在一些具有椭圆形变化的 DNe,这一点非常引人注目,因为这些系统中的伴星预计是光曲线中看不到的低质量冷 M-矮星。这可能表明,我们观测到的系统中,供体恒星的质量原本要大得多,并且在质量转移开始之前经历了显著的核演化,就像之前对 QZ Ser 的观测结果一样。
New orbital periods of high-inclination dwarf novae based on Gaia Alerts photometry
The orbital period of a cataclysmic variable stands as a crucial parameter for investigating the structure and physics of these binary systems, as well as understanding their evolution. We use photometric Gaia data for dwarf novae (DNe) in the quiescent state – which are available for a number of years – to determine new orbital periods and improve or modify previously suggested period values. Two approaches are implemented for selecting high-inclination targets, either eclipsing or with ellipsoidal variations. We determine new orbital periods for 75 DNe and improve ephemerides for 27 more (three of which change significantly), contributing 9.4% of the known DNe periods of between 0.05 and 2.0 days, and doubling the number of known periods exceeding 0.44 days. Their phase-folded light curves are presented and arranged by orbital period, illustrating the transition from short-period systems, dominated by radiation from the accretion disc and the hot spot, to longer-period DNe, where the Roche-lobe-filling secondary star is the primary visual flux source. This transition – which occurs around the well-known period gap (between ∼2 and 3 hours) – is expected, as DNe with larger orbital periods typically harbour more massive donors, which contribute to the visible flux. However, this transition is not abrupt. Within the same range of periods, we observe systems dominated by ellipsoidal variations, where the companion star is clearly visible, as well as others dominated by the disc and the hot spot. The presence of some DNe with ellipsoidal variations near the lower edge of the period gap is striking, as the companions in these systems are expected to be cool low-mass M-dwarfs not visible in the light curve. This could indicate that we are observing systems where the donor star was originally much more massive and underwent significant nuclear evolution before mass-transfer began, as has been suggested previously for QZ Ser.
期刊介绍:
Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.