Your search keyword '"Giuseppe Bono"' showing total 8 results

1. The Not So Simple Stellar System ω Cen. II. Evidence in Support of a Merging Scenario.

Author

Annalisa Calamida, Alice Zocchi, Giuseppe Bono, Ivan Ferraro, Alessandra Mastrobuono-Battisti, Abhijit Saha, Giacinto Iannicola, Armin Rest, Giovanni Strampelli, and Alfredo Zenteno

Subjects

*MAIN sequence (Astronomy), *STELLAR parallax, *EARLY stars, *STAR formation, *SPACE telescopes, *ASTRONOMICAL photometry, *PHOTOMETRY

Abstract

We present multiband photometry covering ∼5° × 5° across ω Cen collected with the Dark Energy Camera on the 4 m Blanco telescope, combined with Hubble Space Telescope and Wide Field Imager data for the central regions. The unprecedented photometric accuracy and field coverage allows us to confirm the different spatial distribution of blue and red main-sequence stars, and of red giant branch (RGB) stars with different metallicities. The ratio of the number of blue to red main-sequence stars shows that the blue main-sequence stellar subpopulation has a more extended spatial distribution compared to the red main-sequence one, with the frequency of blue main-sequence stars increasing at a distance of ∼20′ from ω Cen’s center. Similarly, the more metal-rich RGB stars show a more extended spatial distribution compared to the more metal-poor ones in the outskirts of the cluster. Moreover, the centers of the distributions of metal-rich and metal-poor RGB stars are shifted in different directions with respect to the geometrical center of ω Cen. We constructed stellar density profiles for the blue and red main-sequence stars; they show that the blue main-sequence stellar subpopulation has a more extended spatial distribution compared to the red main-sequence one in the outskirts of ω Cen, confirming the results based on the number ratio. We also computed the ellipticity profile of ω Cen, which has a maximum value of 0.16 at a distance of ∼8′ from the center, and a minimum of 0.05 at ∼30′; the average ellipticity is ∼0.10. The circumstantial evidence presented in this work suggests a merging scenario for the formation of the peculiar stellar system ω Cen. [ABSTRACT FROM AUTHOR]

Published

2020

2. On a New Theoretical Framework for RR Lyrae Stars. II. Mid-infrared Period–Luminosity–Metallicity Relations.

Author

Jillian R. Neeley, Massimo Marengo, Giuseppe Bono, Vittorio F. Braga, Massimo Dall’Ora, Davide Magurno, Marcella Marconi, Nicolas Trueba, Emanuele Tognelli, Pier G. Prada Moroni, Rachael L. Beaton, Wendy L. Freedman, Barry F. Madore, Andrew J. Monson, Victoria Scowcroft, Mark Seibert, and Peter B. Stetson

Subjects

*LUMINOSITY, *STAR clusters, *WAVELENGTHS, *STELLAR oscillations, *HYDRODYNAMICS

Abstract

We present new theoretical period–luminosity–metallicity (PLZ) relations for RR Lyræ stars (RRLs) at Spitzer and WISE wavelengths. The PLZ relations were derived using nonlinear, time-dependent convective hydrodynamical models for a broad range of metal abundances (Z = 0.0001–0.0198). In deriving the light curves, we tested two sets of atmospheric models and found no significant difference between the resulting mean magnitudes. We also compare our theoretical relations to empirical relations derived from RRLs in both the field and in the globular cluster M4. Our theoretical PLZ relations were combined with multi-wavelength observations to simultaneously fit the distance modulus, μ0, and extinction, AV, of both the individual Galactic RRL and of the cluster M4. The results for the Galactic RRL are consistent with trigonometric parallax measurements from Gaia’s first data release. For M4, we find a distance modulus of μ0 = 11.257 ± 0.035 mag with AV = 1.45 ± 0.12 mag, which is consistent with measurements from other distance indicators. This analysis has shown that, when considering a sample covering a range of iron abundances, the metallicity spread introduces a dispersion in the PL relation on the order of 0.13 mag. However, if this metallicity component is accounted for in a PLZ relation, the dispersion is reduced to ∼0.02 mag at mid-infrared wavelengths. [ABSTRACT FROM AUTHOR]

Published

2017

3. The ISLAnds Project. III. Variable Stars in Six Andromeda Dwarf Spheroidal Galaxies.

Author

Matteo Monelli, Carme Gallart, Antonio Aparicio, Sebastian L. Hidalgo, Clara E. Martínez-Vázquez, Kristen B. W. McQuinn, Michael Boylan-Kolchin, Andrew A. Cole, Nicolas F. Martin, Andrew E. Dolphin, Daniel R. Weisz, Giuliana Fiorentino, Edouard J. Bernard, Peter B. Stetson, Alan W. McConnachie, Evan D. Skillman, Giuseppe Bono, and Santi Cassisi

Subjects

*GALAXIES, *CEPHEIDS, *RR Lyrae stars, *HORIZONTAL branch stars, *MILKY Way, *LIGHT curves

Abstract

We present a census of variable stars in six M31 dwarf spheroidal satellites observed with the Hubble Space Telescope. We detect 870 RR Lyrae (RRL) stars in the fields of And I (296), II (251), III (111), XV (117), XVI (8), and XXVIII (87). We also detect a total of 15 Anomalous Cepheids, three eclipsing binaries, and seven field RRL stars compatible with being members of the M31 halo or the Giant Stellar Stream. We derive robust and homogeneous distances to the six galaxies using different methods based on the properties of the RRL stars. Working with the up-to-date set of Period-Wesenheit (I, B–I) relations published by Marconi et al., we obtain distance moduli of μ0 = [24.49, 24.16, 24.36, 24.42, 23.70, 24.43] mag (respectively), with systematic uncertainties of 0.08 mag and statistical uncertainties <0.11 mag. We have considered an enlarged sample of 16 M31 satellites with published variability studies, and compared their pulsational observables (e.g., periods and amplitudes) with those of 15 Milky Way satellites for which similar data are available. The properties of the (strictly old) RRL in both satellite systems do not show any significant difference. In particular, we found a strikingly similar correlation between the mean period distribution of the fundamental RRL pulsators (RRab) and the mean metallicities of the galaxies. This indicates that the old RRL progenitors were similar at the early stage in the two environments, suggesting very similar characteristics for the earliest stages of evolution of both satellite systems. [ABSTRACT FROM AUTHOR]

Published

2017

4. Mass and p-factor of the Type II Cepheid OGLE-LMC-T2CEP-098 in a Binary System.

Author

Bogumił Pilecki, Wolfgang Gieren, Radosław Smolec, Grzegorz Pietrzyński, Ian B. Thompson, Richard I. Anderson, Giuseppe Bono, Igor Soszyński, Pierre Kervella, Nicolas Nardetto, Mónica Taormina, Kazimierz Stȩpień, and Piotr Wielgórski

Subjects

*CEPHEIDS, *PULSATING stars, *BINARY systems (Astronomy), *ASYMPTOTIC giant branch stars, *MASS transfer

Abstract

We present the results of a study of the type II Cepheid (Ppuls = 4.974 days) in the eclipsing binary system OGLE-LMC-T2CEP-098 (Porb = 397.2 days). The Cepheid belongs to the peculiar W Vir group, for which the evolutionary status is virtually unknown. It is the first single-lined system with a pulsating component analyzed using the method developed by Pilecki et al. We show that the presence of a pulsator makes it possible to derive accurate physical parameters of the stars even if radial velocities can be measured for only one of the components. We have used four different methods to limit and estimate the physical parameters, eventually obtaining precise results by combining pulsation theory with the spectroscopic and photometric solutions. The Cepheid radius, mass, and temperature are , , and , respectively, while its companion has a similar size (), but is more massive () and hotter (9500 K). Our best estimate for the p-factor of the Cepheid is . The mass, position on the period–luminosity diagram, and pulsation amplitude indicate that the pulsating component is very similar to the Anomalous Cepheids, although it has a much longer period and is redder in color. The very unusual combination of the components suggest that the system has passed through a mass-transfer phase in its evolution. More complicated internal structure would then explain its peculiarity. [ABSTRACT FROM AUTHOR]

Published

2017

5. New Classical Cepheids in the Inner Part of the Northern Galactic Disk, and Their Kinematics.

Author

Satoshi Tanioka, Noriyuki Matsunaga, Kei Fukue, Laura Inno, Giuseppe Bono, and Naoto Kobayashi

Subjects

*CEPHEIDS, *GALAXY clusters, *GALAXIES, *STELLAR mass, *KINEMATICS, *ASTRONOMICAL spectroscopy

Abstract

The characteristics of the inner Galaxy remain obscured by significant dust extinction, hence infrared surveys are useful for finding young Cepheids whose distances and ages can be accurately determined. A near-infrared photometric and spectroscopic survey was carried out and three classical Cepheids were unveiled in the inner disk, around 20° and 30° in Galactic longitude. The targets feature small Galactocentric distances, 3–5 kpc, and their velocities are important, as they may be under the environmental influence of the Galactic bar. While one of the Cepheids has a radial velocity consistent with the Galactic rotation, the other two are moving significantly slower. We also compare their kinematics with that of high-mass star-forming regions with measured parallactic distances. [ABSTRACT FROM AUTHOR]

Published

2017

6. THE CARNEGIE-CHICAGO HUBBLE PROGRAM. I. AN INDEPENDENT APPROACH TO THE EXTRAGALACTIC DISTANCE SCALE USING ONLY POPULATION II DISTANCE INDICATORS.

Author

In Sung Jang, Myung Gyoon Lee, Andrew J. Monson, Rachael L. Beaton, Barry F. Madore, Erika K. Carlson, Juna A. Kollmeier, Jeffrey A. Rich, Victoria Scowcroft, Mark Seibert, Laura Sturch, Soung-Chul Yang, Wendy L. Freedman, Dylan Hatt, Giuseppe Bono, Gisella Clementini, Alessia Garofalo, and Meredith J. Durbin

Subjects

*STELLAR parallax, *POPULATION II (Astronomy), *VARIABLE stars, *RR Lyrae stars, *INTERSTELLAR reddening

Abstract

We present an overview of the Carnegie-Chicago Hubble Program, an ongoing program to obtain a 3% measurement of the Hubble constant (H0) using alternative methods to the traditional Cepheid distance scale. We aim to establish a completely independent route to H0 using RR Lyrae variables, the tip of the red giant branch (TRGB), and Type Ia supernovae (SNe Ia). This alternative distance ladder can be applied to galaxies of any Hubble type, of any inclination, and, using old stars in low-density environments, is robust to the degenerate effects of metallicity and interstellar extinction. Given the relatively small number of SNe Ia host galaxies with independently measured distances, these properties provide a great systematic advantage in the measurement of H0 via the distance ladder. Initially, the accuracy of our value of H0 will be set by the five Galactic RR Lyrae calibrators with Hubble Space Telescope Fine-Guidance Sensor parallaxes. With Gaia, both the RR Lyrae zero-point and TRGB method will be independently calibrated, the former with at least an order of magnitude more calibrators and the latter directly through parallax measurement of tip red giants. As the first end-to-end “distance ladder” completely independent of both Cepheid variables and the Large Magellanic Cloud, this path to H0 will allow for the high-precision comparison at each rung of the traditional distance ladder that is necessary to understand tensions between this and other routes to H0. [ABSTRACT FROM AUTHOR]

Published

2016

7. THE ARAUCARIA PROJECT: A STUDY OF THE CLASSICAL CEPHEID IN THE ECLIPSING BINARY SYSTEM OGLE LMC562.05.9009 IN THE LARGE MAGELLANIC CLOUD.

Author

Wolfgang Gieren, Bogumił Pilecki, Grzegorz Pietrzyński, Dariusz Graczyk, Andrzej Udalski, Igor Soszyński, Ian B. Thompson, Pier Giorgio Prada Moroni, Radosław Smolec, Piotr Konorski, Marek Górski, Paulina Karczmarek, Ksenia Suchomska, Mónica Taormina, Alexandre Gallenne, Jesper Storm, Giuseppe Bono, Márcio Catelan, Michał Szymański, and Szymon Kozłowski

Subjects

*CEPHEIDS, *ECLIPSING binaries, *STELLAR orbits, *STELLAR mass, *LARGE magellanic cloud

Abstract

We present a detailed study of the classical Cepheid in the double-lined, highly eccentric eclipsing binary system OGLE-LMC562.05.9009. The Cepheid is a fundamental mode pulsator with a period of 2.988 days. The orbital period of the system is 1550 days. Using spectroscopic data from three 4–8-m telescopes and photometry spanning 22 years, we were able to derive the dynamical masses and radii of both stars with exquisite accuracy. Both stars in the system are very similar in mass, radius, and color, but the companion is a stable, non-pulsating star. The Cepheid is slightly more massive and bigger (M1 = 3.70 ± 0.03 M⊙, R1 = 28.6 ± 0.2 R⊙) than its companion (M2 = 3.60 ± 0.03 M⊙, R2 = 26.6 ± 0.2 R⊙). Within the observational uncertainties both stars have the same effective temperature of 6030 ± 150 K. Evolutionary tracks place both stars inside the classical Cepheid instability strip, but it is likely that future improved temperature estimates will move the stable giant companion just beyond the red edge of the instability strip. Within current observational and theoretical uncertainties, both stars fit on a 205 Myr isochrone arguing for their common age. From our model, we determine a value of the projection factor of p = 1.37 ± 0.07 for the Cepheid in the OGLE-LMC562.05.9009 system. This is the second Cepheid for which we could measure its p-factor with high precision directly from the analysis of an eclipsing binary system, which represents an important contribution toward a better calibration of Baade-Wesselink methods of distance determination for Cepheids. [ABSTRACT FROM AUTHOR]

Published

2015

8. LINE-DEPTH RATIOS IN H-BAND SPECTRA TO DETERMINE EFFECTIVE TEMPERATURES OF G- AND K-TYPE GIANTS AND SUPERGIANTS.

Author

Kei Fukue, Noriyuki Matsunaga, Chikako Yasui, Sohei Kondo, Satoshi Hamano, Takayuki Arasaki, Naoto Kobayashi, Yuji Ikeda, Ryo Yamamoto, Takuji Tsujimoto, Giuseppe Bono, and Laura Inno

Subjects

*GIANT stars, *STELLAR atmospheres, *TEMPERATURE of stars, *MILKY Way, *INFRARED cameras

Abstract

The stellar effective temperature is the fundamental parameter of stellar atmospheres. It characterizes the spectra and plays an essential role in chemical abundance analysis. Previous optical studies have shown that line-depth ratios (LDRs) are good indicators of the effective temperature. Essentially, the ratios of absorption lines with different excitation potentials can be used as temperature scales. The most important advantage of LDRs is their robustness against interstellar reddening and extinction. Furthermore, the scales are constructed and calibrated empirically by observables. Although this method is well-established for optical spectra, we require infrared high-resolution spectroscopy to access the most obscured stars in the Galactic disk and thereby understand the Milky Way’s structure and evolution in the innermost region. This study newly derives the temperature scales from the LDRs in infrared spectra. We explored LDRs in the high-resolution H-band spectra (1.4–1.8 μm) of well-known stars in the solar neighborhood obtained with Subaru/infrared camera and spectrograph. We found nine pairs of absorption lines whose LDRs allow us to determine the temperatures of G- and K-type giants/supergiants to an accuracy of ∼60 K. Checking the dependency of our scales on stellar parameters, we found that our developed temperature scales may slightly bias the estimates for low-metal stars, [Fe/H] < dex. [ABSTRACT FROM AUTHOR]

Published

2015