Light-curve analysis of KOI 2700b: the second extrasolar planet with a comet-like tail

Garai, Z.

doi:10.1051/0004-6361/201629676

Cited by 9 publications

(7 citation statements)

References 35 publications

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“…This detrending method can effectively remove the long-term variability (mainly variability of the host star due to spots and rotation) while it does not introduce any nonlinear trend to the data, see Fig. 2 and, e.g., Garai (2018). Outliers were cleaned similarly as in the case of the MuSCAT2 observations.…”

Section: Observations and Data Reductionmentioning

confidence: 99%

Is the orbit of the exoplanet WASP-43b really decaying? TESS and MuSCAT2 observations confirm no detection

Garai

Pribulla

Parviainen

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Up to now, WASP-12b is the only hot Jupiter confirmed to have a decaying orbit. The case of WASP-43b is still under debate. Recent studies preferred or ruled out the orbital decay scenario, but further precise transit timing observations are needed to definitively confirm or refute the period change of WASP-43b. This possibility is given by the Transiting Exoplanet Survey Satellite (TESS) space telescope. In this work we used the available TESS data, multi-colour photometry data obtained with the Multicolor Simultaneous Camera for studying Atmospheres of Transiting exoplanets 2 (MuSCAT2) and literature data to calculate the period change rate of WASP-43b and to improve its precision, and to refine the parameters of the WASP-43 planetary system. Based on the observed-minus-calculated data of 129 mid-transit times in total, covering a time baseline of about 10 years, we obtained an improved period change rate of $\dot{P} = -0.6 \pm 1.2$ ms yr−1 that is consistent with a constant period well within 1σ. We conclude that new TESS and MuSCAT2 observations confirm no detection of WASP-43b orbital decay.

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Section: Observations and Data Reductionmentioning

confidence: 99%

Is the orbit of the exoplanet WASP-43b really decaying? TESS and MuSCAT2 observations confirm no detection

Garai

Pribulla

Parviainen

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…It would also be possible to feed TLS with an analytic description of exocometary transits (Rappaport et al 2018;Kennedy et al 2018) or disintegrating planets with comet-like tails (Bochinski et al 2015;Garai 2018), atmospheric refraction (Dalba 2017(Dalba , 2018, exoplanetary rings (Barnes & Fortney 2004;Ohta et al 2009;Tusnski & Valio 2011;Aizawa et al 2017;Hatchett et al 2018) or artificial shapes such as rectangles (Arnold 2005) as well as starshades at the Lagrange points (Gaidos 2017;Moores & Welch 2018).…”

Section: Arbitrary Signal Shapesmentioning

confidence: 99%

Optimized transit detection algorithm to search for periodic transits of small planets

Hippke

Heller

2019

A&A

211

103

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We present a new method to detect planetary transits from time-series photometry, the transit least squares (TLS) algorithm. TLS searches for transit-like features while taking the stellar limb darkening and planetary ingress and egress into account. We have optimized TLS for both signal detection efficiency (SDE) of small planets and computational speed. TLS analyses the entire, unbinned phase-folded light curve. We compensated for the higher computational load by (i.) using algorithms such as "Mergesort" (for the trial orbital phases) and by (ii.) restricting the trial transit durations to a smaller range that encompasses all known planets, and using stellar density priors where available. A typical K2 light curve, including 80 d of observations at a cadence of 30 min, can be searched with TLS in ∼ 10 s real time on a standard laptop computer, as fast as the widely used box least squares (BLS) algorithm. We perform a transit injection-retrieval experiment of Earth-sized planets around sun-like stars using synthetic light curves with 110 ppm white noise per 30 min cadence, corresponding to a photometrically quiet K P = 12 star observed with Kepler. We determine the SDE thresholds for both BLS and TLS to reach a false positive rate of 1 % to be SDE = 7 in both cases. The resulting true positive (or recovery) rates are ∼ 93 % for TLS and ∼ 76 % for BLS, implying more reliable detections with TLS. We also test TLS with the K2 light curve of the TRAPPIST-1 system and find six of seven Earth-sized planets using an iterative search for increasingly lower signal detection efficiency, the phase-folded transit of the seventh planet being affected by a stellar flare. TLS is more reliable than BLS in finding any kind of transiting planet but it is particularly suited for the detection of small planets in long time series from Kepler, TESS, and PLATO. We make our python implementation of TLS publicly available.

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“…At the same time, only the signatures of the dust component are detectable in such studies. Until now, the manifestations of dust have been noticed on decaying rocky planets in the form of tails (e.g., Brogi et al 2012;Budaj 2013;Garai 2018;Sanchis-Ojeda et al 2015). The presence of dust was also reported at altitudes of ∼3000 km in gaseous giant exoplanets (Huitson et al 2012;Wang & Dai 2019), and it is quite possible that such dust is dragged by the escaping planetary upper atmospheric material driven by stellar X-ray and ultraviolet (XUV) heating and tidal forces (Shaikhislamov et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Dusty phenomena in the vicinity of giant exoplanets

Arkhypov

Khodachenko

Hanslmeier

2019

A&A

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Context. Hitherto, searches for exoplanetary dust have focused on the tails of decaying rocky or approaching icy bodies only at short circumstellar distances. At the same time, dust has been detected in the upper atmospheric layers of hot jupiters, which are subject to intensive mass loss. The erosion and/or tidal decay of hypothetic moonlets might be another possible source of dust around giant gaseous exoplanets. Moreover, volcanic activity and exozodiacal dust background may additionally contribute to exoplanetary dusty environments. Aims. In the present study, we look for photometric manifestations of dust around different kinds of exoplanets (mainly giants). Methods. We used linear approximation of pre- and post-transit parts of the long-cadence transit light curves (TLCs) of 118 Kepler objects of interest after their preliminary whitening and phase-folding. We then determined the corresponding flux gradients G1 and G2, respectively. These gradients were defined before and after the transit border for two different time intervals: (a) from 0.03 to 0.16 days and (b) from 0.01 to 0.05 days, which correspond to the distant and adjoining regions near the transiting object, respectively. Statistical analysis of gradients G1 and G2 was used for detection of possible dust manifestation. Results. It was found that gradients G1 and G2 in the distant region are clustered around zero, demonstrating the absence of artifacts generated during the light curve processing. However, in the adjoining region, 17 cases of hot jupiters show significantly negative gradients, G1, whereas the corresponding values of G2 remain around zero. The analysis of individual TLCs reveals the localized pre-transit decrease of flux, which systematically decreases G1. This effect was reproduced with the models using a stochastic obscuring precursor ahead of the planet. Conclusions. Since only a few TLCs show the presence of such pre-transit anomalies with no analogous systematic effect in the post-transit phase, we conclude that the detected pre-transit obscuration is a real planet-related phenomenon. Such phenomena may be caused by dusty atmospheric outflows or background circumstellar dust compressed in front of the mass-losing exoplanet, the study of which requires dedicated physical modeling and numeric simulations. Of certain importance may be the retarding of exozodiacal dust relative to the planet by the Poynting-Robertson effect leading to dust accumulation in electrostatic or magnetic traps in front of the planet.

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Light-curve analysis of KOI 2700b: the second extrasolar planet with a comet-like tail

Cited by 9 publications

References 35 publications

Is the orbit of the exoplanet WASP-43b really decaying? TESS and MuSCAT2 observations confirm no detection

Is the orbit of the exoplanet WASP-43b really decaying? TESS and MuSCAT2 observations confirm no detection

Optimized transit detection algorithm to search for periodic transits of small planets

Dusty phenomena in the vicinity of giant exoplanets

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