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Main Authors: Sáez-Carvajal, Catalina, Vogt, Nikolaus, Zorotovic, Mónica, García-Veas, Javiera, Aravena-Rojas, Gonzalo, Dumond, Lukas, Figueroa-Tapia, Felipe, López-Bonilla, Yanina, Rodriguez-Jimenez, Abigali, Vega-Manubens, Ignacio, Grawe, Benjamín
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.09566
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author Sáez-Carvajal, Catalina
Vogt, Nikolaus
Zorotovic, Mónica
García-Veas, Javiera
Aravena-Rojas, Gonzalo
Dumond, Lukas
Figueroa-Tapia, Felipe
López-Bonilla, Yanina
Rodriguez-Jimenez, Abigali
Vega-Manubens, Ignacio
Grawe, Benjamín
author_facet Sáez-Carvajal, Catalina
Vogt, Nikolaus
Zorotovic, Mónica
García-Veas, Javiera
Aravena-Rojas, Gonzalo
Dumond, Lukas
Figueroa-Tapia, Felipe
López-Bonilla, Yanina
Rodriguez-Jimenez, Abigali
Vega-Manubens, Ignacio
Grawe, Benjamín
contents 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/modify previously suggested 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 0.05-2.0 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 (around 2-3 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 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.
format Preprint
id arxiv_https___arxiv_org_abs_2411_09566
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle New orbital periods of high-inclination dwarf novae based on Gaia Alerts photometry
Sáez-Carvajal, Catalina
Vogt, Nikolaus
Zorotovic, Mónica
García-Veas, Javiera
Aravena-Rojas, Gonzalo
Dumond, Lukas
Figueroa-Tapia, Felipe
López-Bonilla, Yanina
Rodriguez-Jimenez, Abigali
Vega-Manubens, Ignacio
Grawe, Benjamín
Solar and Stellar Astrophysics
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/modify previously suggested 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 0.05-2.0 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 (around 2-3 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 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.
title New orbital periods of high-inclination dwarf novae based on Gaia Alerts photometry
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2411.09566