Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet

The source GJ1132 is a nearby red dwarf known to host a transiting Earth-size planet. After its initial detection, we pursued an intense follow-up with the HARPS velocimeter. We now confirm the detection of GJ1132b with radial velocities alone. We refined its orbital parameters, and in particular, i...

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Detalles Bibliográficos
Publicado: 2018
Materias:
Planetary systems
Stars: late-type
Techniques: radial velocities
Astrophysics
Markov processes
Orbits
Stars
Velocity
Equilibrium temperatures
Gaussian Processes
Markov Chain Monte-Carlo
Orbital parameters
Planetary system
Posterior probability
Stars:late type
Earth (planet)
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00046361_v618_n_p_Bonfils
http://hdl.handle.net/20.500.12110/paper_00046361_v618_n_p_Bonfils
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_00046361_v618_n_p_Bonfils
record_format dspace
spelling paper:paper_00046361_v618_n_p_Bonfils2023-06-08T14:28:24Z Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet Planetary systems Stars: late-type Techniques: radial velocities Astrophysics Markov processes Orbits Stars Velocity Equilibrium temperatures Gaussian Processes Markov Chain Monte-Carlo Orbital parameters Planetary system Posterior probability Stars:late type Techniques: radial velocities Earth (planet) The source GJ1132 is a nearby red dwarf known to host a transiting Earth-size planet. After its initial detection, we pursued an intense follow-up with the HARPS velocimeter. We now confirm the detection of GJ1132b with radial velocities alone. We refined its orbital parameters, and in particular, its mass (m b = 1.66 ± 0.23 M), density (ρ b = 6.3 ± 1.3 g cm -3 ), and eccentricity (e b < 0.22; 95%). We also detected at least one more planet in the system. GJ1132c is a super-Earth with period P c = 8.93 ± 0.01 days and minimum mass m c sini c = 2.64 ± 0.44 M. Receiving about 1.9 times more flux than Earth in our solar system, its equilibrium temperature is that of a temperate planet (T eq = 230-300 K for albedos A = 0.75 - 0.00), which places GJ1132c near the inner edge of the so-called habitable zone. Despite an a priori favorable orientation for the system, Spitzer observations reject most transit configurations, leaving a posterior probability <1% that GJ1132c transits. GJ1132(d) is a third signal with period P d = 177 ± 5 days attributed to either a planet candidate with minimum mass m d sin i d = 8.4 -2.5 +1.7 M or stellar activity. Its Doppler signal is the most powerful in our HARPS time series but appears on a timescale where either the stellar rotation or a magnetic cycle are viable alternatives to the planet hypothesis. On the one hand, the period is different than that measured for the stellar rotation (~125 days), and a Bayesian statistical analysis we performed with a Markov chain Monte Carlo and Gaussian processes demonstrates that the signal is better described by a Keplerian function than by correlated noise. On the other hand, periodograms of spectral indices sensitive to stellar activity show power excess at similar periods to that of this third signal, and radial velocity shifts induced by stellar activity can also match a Keplerian function. We, therefore, prefer to leave the status of GJ1132(d) undecided. © ESO 2018. 2018 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00046361_v618_n_p_Bonfils http://hdl.handle.net/20.500.12110/paper_00046361_v618_n_p_Bonfils
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Planetary systems
Stars: late-type
Techniques: radial velocities
Astrophysics
Markov processes
Orbits
Stars
Velocity
Equilibrium temperatures
Gaussian Processes
Markov Chain Monte-Carlo
Orbital parameters
Planetary system
Posterior probability
Stars:late type
Techniques: radial velocities
Earth (planet)
spellingShingle Planetary systems
Stars: late-type
Techniques: radial velocities
Astrophysics
Markov processes
Orbits
Stars
Velocity
Equilibrium temperatures
Gaussian Processes
Markov Chain Monte-Carlo
Orbital parameters
Planetary system
Posterior probability
Stars:late type
Techniques: radial velocities
Earth (planet)
Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
topic_facet Planetary systems
Stars: late-type
Techniques: radial velocities
Astrophysics
Markov processes
Orbits
Stars
Velocity
Equilibrium temperatures
Gaussian Processes
Markov Chain Monte-Carlo
Orbital parameters
Planetary system
Posterior probability
Stars:late type
Techniques: radial velocities
Earth (planet)
description The source GJ1132 is a nearby red dwarf known to host a transiting Earth-size planet. After its initial detection, we pursued an intense follow-up with the HARPS velocimeter. We now confirm the detection of GJ1132b with radial velocities alone. We refined its orbital parameters, and in particular, its mass (m b = 1.66 ± 0.23 M), density (ρ b = 6.3 ± 1.3 g cm -3 ), and eccentricity (e b < 0.22; 95%). We also detected at least one more planet in the system. GJ1132c is a super-Earth with period P c = 8.93 ± 0.01 days and minimum mass m c sini c = 2.64 ± 0.44 M. Receiving about 1.9 times more flux than Earth in our solar system, its equilibrium temperature is that of a temperate planet (T eq = 230-300 K for albedos A = 0.75 - 0.00), which places GJ1132c near the inner edge of the so-called habitable zone. Despite an a priori favorable orientation for the system, Spitzer observations reject most transit configurations, leaving a posterior probability <1% that GJ1132c transits. GJ1132(d) is a third signal with period P d = 177 ± 5 days attributed to either a planet candidate with minimum mass m d sin i d = 8.4 -2.5 +1.7 M or stellar activity. Its Doppler signal is the most powerful in our HARPS time series but appears on a timescale where either the stellar rotation or a magnetic cycle are viable alternatives to the planet hypothesis. On the one hand, the period is different than that measured for the stellar rotation (~125 days), and a Bayesian statistical analysis we performed with a Markov chain Monte Carlo and Gaussian processes demonstrates that the signal is better described by a Keplerian function than by correlated noise. On the other hand, periodograms of spectral indices sensitive to stellar activity show power excess at similar periods to that of this third signal, and radial velocity shifts induced by stellar activity can also match a Keplerian function. We, therefore, prefer to leave the status of GJ1132(d) undecided. © ESO 2018.
title Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
title_short Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
title_full Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
title_fullStr Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
title_full_unstemmed Radial velocity follow-up of GJ1132 with HARPS: A precise mass for planet b and the discovery of a second planet
title_sort radial velocity follow-up of gj1132 with harps: a precise mass for planet b and the discovery of a second planet
publishDate 2018
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00046361_v618_n_p_Bonfils
http://hdl.handle.net/20.500.12110/paper_00046361_v618_n_p_Bonfils
_version_ 1768542295116742656

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