Your search keyword '"de Miera, F. Cruz-Saenz"' showing total 3 results

1. Tracing episodic accretion with NOEMA: FU Orionis-type stars and their millimeter environment.

Author

Fehér, O., Kóspál, Á., de Miera, F. Cruz-Saenz, Ábrahám, P., Hogerheijde, M.R., Brinch, Ch., and Semenov, D.

Subjects

ACCRETION (Astrophysics), INFRARED radiation, INTERFEROMETRY, LIGHT curves, STAR formation

Abstract

The earliest phases of star formation are characterised by intense mass accretion from the circumstellar disk to the central star. One group of lowmass young stellar objects, FU Orionis-type stars (FUors) exhibit accretion rate peaks accompanied by bright eruptions in the optical and infrared regime. The occurance of these outbursts might solve the luminosity problem of protostars, play a key role in accumulating the final stellar mass, and have a significant effiect on the parameters of the envelope and the disk. We are performing a systematic investigation of FUors with millimeter interferometry using NOEMA and ALMA to study the outburst events and examine whether FUors represent normal young stars in exceptional times or are unusual objects. The targeted FUors show very diverse circumstellar morphologies with envelope parameters similar to those of both Class I and Class II systems, but their disks are more massive and more compact than T Tauri disks. To shed light onto the process of disk-formation, accretion, and to what role FUors play in low-mass starformation, we require the identification and light curve monitoring of as many of these stars as possible, together with the multi-wavelength and multi-scale mapping of their circumstellar environment. [ABSTRACT FROM AUTHOR]

Published

2022

2. 94 Ceti: a triple star with a planet and dust disc.

Author

Wiegert, J., Faramaz, V., and de Miera, F. Cruz-Saenz

Subjects

TRIPLE stars, GAS giants, SPACE debris, PLANETARY orbits, STELLAR evolution, SPECTRAL energy distribution

Abstract

94 Ceti is a triple star system with a circumprimary gas giant planet and far-infrared excess. Such excesses around main sequence stars are likely due to debris discs, and are considered as signposts of planetary systems and, therefore, provide important insights into the configuration and evolution of the planetary system. Consequently, to learn more about the 94 Ceti system, we aim to model the dust emission precisely to fit its observed spectral energy distribution and to simulate its orbital dynamics. We interpret our APEX bolometric observations and complement them with archived Spitzer and Herschel bolometric data to explore the stellar excess and to map out background sources in the fields. Dynamical simulations and 3D radiative transfer calculations were used to constrain the debris disc configurations and model the dust emission. The best-fitting dust disc model for 94 Ceti implies a circumbinary disc around the secondary pair, limited by dynamics to radii smaller than 40 au and with a grainsize power-law distribution of ~a-3.5. This model exhibits a dust-to-star luminosity ratio of 4.6 ± 0.4× 10-6. The system is dynamically stable and N-body symplectic simulation results are consistent with semi-analytical equations that describe orbits in binary systems. In the observations, we also find tentative evidence of a circumtertiary ring that could be edge-on. [ABSTRACT FROM AUTHOR]

Published

2016

3. Lithium abundance in a sample of solar-like stars.

Author

López-Valdivia, R., Hernández-Águila, J. B., Bertone, E., Chávez, M., de Miera, F. Cruz-Saenz, and Amazo-Gómez, E. M.

Subjects

LITHIUM, COSMIC abundances, ASTRONOMICAL observations, STELLAR evolution, STAR formation

Abstract

We report on the determination of the lithium abundance [A(Li)] of 52 solar-like stars. For 41 objects the A(Li) here presented corresponds to the first measurement. We have measured the equivalent widths of the 6708 Å lithium feature in high-resolution spectroscopic images (R ~ 80 000), obtained at the Observatorio Astrofísico Guillermo Haro (Sonora, Mexico), as part of the first scientific observations of the revitalized Lunar and Planetary Laboratory (LPL) Echelle Spectrograph, now known as the Cananea High-resolution Spectrograph (CanHiS). Lithium abundances were derived with the Fortran code moog, using as fundamental input a set of atmospheric parameters recently obtained by our group. With the help of an additional small sample with previous A(Li) determinations, we demonstrate that our lithium abundances are in agreement, to within uncertainties, with other works. Two target objects stand out from the rest of the sample. The star BD+47 3218 (Teff = 6050 ± 52 K, A(Li) = 1.86 ± 0.07 dex) lies inside the so-called lithium desert in the A(Li)-Teff plane. The other object, BD+28 4515, has an A(Li) = 3.05 ± 0.07 dex, which is the highest of our sample and compatible with the expected abundances of relatively young stars. [ABSTRACT FROM AUTHOR]

Published

2015