Temperature condensation trend in the debris-disk binary system ζ2 Reticuli

Context. Detailed abundance studies have reported different trends between samples of stars with and without planets, possibly related to the planet formation process. Whether these differences are still present between samples of stars with and without debris disk is still unclear. Aims. We explore...

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Autores principales: Saffe, C., Flores, M., Jaque Arancibia, M., Buccino, A., Jofré, E.
Formato: JOUR
Materias:
Binaries: general
Planetary systems
Stars: abundances
Stars: individual: ζ1Ret
Stars: individual: ζ2Ret
Bins
Condensation
Debris
Orbits
Planets
Refractory materials
Systems (metallurgical)
Condensation temperature
Differential calculation
Galactic chemical evolutions
Local thermodynamic equilibrium
Planetary system
Stars: individual
Stars
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00046361_v588_n_p_Saffe
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_00046361_v588_n_p_Saffe
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spelling todo:paper_00046361_v588_n_p_Saffe2023-10-03T14:00:57Z Temperature condensation trend in the debris-disk binary system ζ2 Reticuli Saffe, C. Flores, M. Jaque Arancibia, M. Buccino, A. Jofré, E. Binaries: general Planetary systems Stars: abundances Stars: individual: ζ1Ret Stars: individual: ζ2Ret Bins Condensation Debris Orbits Planets Refractory materials Systems (metallurgical) Binaries: general Condensation temperature Differential calculation Galactic chemical evolutions Local thermodynamic equilibrium Planetary system Stars: abundances Stars: individual Stars Context. Detailed abundance studies have reported different trends between samples of stars with and without planets, possibly related to the planet formation process. Whether these differences are still present between samples of stars with and without debris disk is still unclear. Aims. We explore condensation temperature Tc trends in the unique binary system ζ1 Ret -ζ2 Ret to determine whether there is a depletion of refractories that could be related to the planet formation process. The star ζ2 Ret hosts a debris disk which was detected by an IR excess and confirmed by direct imaging and numerical simulations, while ζ1 Ret does not present IR excess or planets. These characteristics convert ζ2 Ret in a remarkable system where their binary nature together with the strong similarity of both components allow us, for the first time, to achieve the highest possible abundance precision in this system. Methods. We carried out a high-precision abundance determination in both components of the binary system via a line-by-line, strictly differential approach. First we used the Sun as a reference and then we used ζ2 Ret. The stellar parameters Teff, log g, [Fe/H], and vturb were determined by imposing differential ionization and excitation equilibrium of Fe I and Fe II lines, with an updated version of the program FUNDPAR, together with plane-parallel local thermodynamic equilibrium ATLAS9 model atmospheres and the MOOG code. We then derived detailed abundances of 24 different species with equivalent widths and spectral synthesis with the MOOG program. The chemical patterns were compared with a recently calculated solar-twins Tc trend, and then mutually between both stars of the binary system. The rocky mass of depleted refractory material was estimated according to recent data. Results. The star ζ1 Ret is found to be slightly more metal rich than ζ2 Ret by ∼0.02 dex. In the differential calculation of ζ1 Ret using ζ2 Ret as reference, the abundances of the refractory elements are higher than the volatile elements, and the trend of the refractory elements with Tc shows a positive slope. These results together show a lack of refractory elements in ζ2 Ret (a debris-disk host) relative to ζ1 Ret. The Tc trend would be in agreement with the proposed signature of planet formation rather than possible galactic chemical evolution or age effects, which are largely diminished here. Then, following the recent interpretation, we propose a scenario in which the refractory elements depleted in ζ2 Ret are possibly locked up in the rocky material that orbits this star and produce the debris disk observed around this object. We estimated a lower limit of Mrock ∼ 3 M⊕ for the rocky mass of depleted material, which is compatible with rough estimations of 3-50 M⊕ of a debris disk mass around a solar-type star. © ESO, 2016. Fil:Buccino, A. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00046361_v588_n_p_Saffe
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Binaries: general
Planetary systems
Stars: abundances
Stars: individual: ζ1Ret
Stars: individual: ζ2Ret
Bins
Condensation
Debris
Orbits
Planets
Refractory materials
Systems (metallurgical)
Binaries: general
Condensation temperature
Differential calculation
Galactic chemical evolutions
Local thermodynamic equilibrium
Planetary system
Stars: abundances
Stars: individual
Stars
spellingShingle Binaries: general
Planetary systems
Stars: abundances
Stars: individual: ζ1Ret
Stars: individual: ζ2Ret
Bins
Condensation
Debris
Orbits
Planets
Refractory materials
Systems (metallurgical)
Binaries: general
Condensation temperature
Differential calculation
Galactic chemical evolutions
Local thermodynamic equilibrium
Planetary system
Stars: abundances
Stars: individual
Stars
Saffe, C.
Flores, M.
Jaque Arancibia, M.
Buccino, A.
Jofré, E.
Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
topic_facet Binaries: general
Planetary systems
Stars: abundances
Stars: individual: ζ1Ret
Stars: individual: ζ2Ret
Bins
Condensation
Debris
Orbits
Planets
Refractory materials
Systems (metallurgical)
Binaries: general
Condensation temperature
Differential calculation
Galactic chemical evolutions
Local thermodynamic equilibrium
Planetary system
Stars: abundances
Stars: individual
Stars
description Context. Detailed abundance studies have reported different trends between samples of stars with and without planets, possibly related to the planet formation process. Whether these differences are still present between samples of stars with and without debris disk is still unclear. Aims. We explore condensation temperature Tc trends in the unique binary system ζ1 Ret -ζ2 Ret to determine whether there is a depletion of refractories that could be related to the planet formation process. The star ζ2 Ret hosts a debris disk which was detected by an IR excess and confirmed by direct imaging and numerical simulations, while ζ1 Ret does not present IR excess or planets. These characteristics convert ζ2 Ret in a remarkable system where their binary nature together with the strong similarity of both components allow us, for the first time, to achieve the highest possible abundance precision in this system. Methods. We carried out a high-precision abundance determination in both components of the binary system via a line-by-line, strictly differential approach. First we used the Sun as a reference and then we used ζ2 Ret. The stellar parameters Teff, log g, [Fe/H], and vturb were determined by imposing differential ionization and excitation equilibrium of Fe I and Fe II lines, with an updated version of the program FUNDPAR, together with plane-parallel local thermodynamic equilibrium ATLAS9 model atmospheres and the MOOG code. We then derived detailed abundances of 24 different species with equivalent widths and spectral synthesis with the MOOG program. The chemical patterns were compared with a recently calculated solar-twins Tc trend, and then mutually between both stars of the binary system. The rocky mass of depleted refractory material was estimated according to recent data. Results. The star ζ1 Ret is found to be slightly more metal rich than ζ2 Ret by ∼0.02 dex. In the differential calculation of ζ1 Ret using ζ2 Ret as reference, the abundances of the refractory elements are higher than the volatile elements, and the trend of the refractory elements with Tc shows a positive slope. These results together show a lack of refractory elements in ζ2 Ret (a debris-disk host) relative to ζ1 Ret. The Tc trend would be in agreement with the proposed signature of planet formation rather than possible galactic chemical evolution or age effects, which are largely diminished here. Then, following the recent interpretation, we propose a scenario in which the refractory elements depleted in ζ2 Ret are possibly locked up in the rocky material that orbits this star and produce the debris disk observed around this object. We estimated a lower limit of Mrock ∼ 3 M⊕ for the rocky mass of depleted material, which is compatible with rough estimations of 3-50 M⊕ of a debris disk mass around a solar-type star. © ESO, 2016.
format JOUR
author Saffe, C.
Flores, M.
Jaque Arancibia, M.
Buccino, A.
Jofré, E.
author_facet Saffe, C.
Flores, M.
Jaque Arancibia, M.
Buccino, A.
Jofré, E.
author_sort Saffe, C.
title Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
title_short Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
title_full Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
title_fullStr Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
title_full_unstemmed Temperature condensation trend in the debris-disk binary system ζ2 Reticuli
title_sort temperature condensation trend in the debris-disk binary system ζ2 reticuli
url http://hdl.handle.net/20.500.12110/paper_00046361_v588_n_p_Saffe
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AT floresm temperaturecondensationtrendinthedebrisdiskbinarysystemz2reticuli
AT jaquearancibiam temperaturecondensationtrendinthedebrisdiskbinarysystemz2reticuli
AT buccinoa temperaturecondensationtrendinthedebrisdiskbinarysystemz2reticuli
AT jofree temperaturecondensationtrendinthedebrisdiskbinarysystemz2reticuli
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