Your search keyword '"Çelik Orhan, Z"' showing total 9 results

1. Structure and composition of Jupiter, Saturn, Uranus, and Neptune under different constraints and distortion due to rotation.

Author

Yıldız, M, Çelik Orhan, Z, Örtel, S, and Çakır, T

Subjects

*JUPITER (Planet), *URANUS (Planet), *NEPTUNE (Planet), *NATURAL satellites, *PLANETARY interiors, *SATURN (Planet)

Abstract

The radii of planets serve as significant constraints for their internal structure. Despite the complexity of planetary internal structure compared to stars, substantial advancements have been made in this field. The most critical uncertainties stem from the chemical composition and equation of state of planetary material. Using the MESA code, we construct rotating and non-rotating interior models for Jupiter and Saturn and sought to align these models to the observed radii. Rotation exerts a significant influence on their structures, distorting planetary, and stellar structures in distinct ways. Regarding gas planets' structure, two pivotal uncertain parameters depend on a possible separation between hydrogen and helium in the protosolar disc gas due to unequal evaporation between these two gases. In an extreme scenario where only hydrogen is lost and no heavy elements or helium are lost, Jupiter and Saturn would have a core mass of zero. However, this approach fails to yield a solution for Uranus and Neptune. Instead, our models indicate that hydrogen and helium were likely lost together during the protosolar disc phase, resulting in core masses of approximately 40, 25, 14, and 12 M⊕ for Jupiter, Saturn, Neptune, and Uranus, respectively. These findings are highly compatible with the observed mass–radius relationship of exoplanets, as well as the seismic and Juno data for Jupiter's near-surface temperature. [ABSTRACT FROM AUTHOR]

Published

2024

2. Analysing mixed modes of the four solar-like oscillating subgiant stars.

Author

Çelik Orhan, Z, Yıldız, M, and Örtel, S

Subjects

*STELLAR populations, *STELLAR oscillations, *ASTROPHYSICS, *FREQUENCIES of oscillating systems, *GRAVITY

Abstract

The observation of an unprecedented number of solar-like oscillating subgiant (SG) stars by the Kepler and TESS missions is crucial for the asteroseismic characterization of these stars, stellar population studies, and the study of stellar evolution theories. Owing to these missions, the fundamental parameters of the solar-like oscillating stars are precisely calculated from the evolution codes using the observed oscillation frequencies. Herein, we considered four solar-like oscillating SG stars. We obtained the fundamental parameters of the SG stars by constructing interior models using asteroseismic and non-asteroseismic observed parameters. The interior models of the four SG stars are constructed using the Modules for Experiments in Stellar Astrophysics code to effectively determine the fundamental properties. Using this method, the four solar-like oscillating SG stars are found to have masses and radii within the ranges of 1.16–1.75 M⊙ and 2.26–3.17 R⊙, respectively. The estimation accuracy of the typical asteroseismic radius, mass, and age is increased by fitting the observed and model reference frequencies. The typical uncertainties of the mass and radius are 3–4 |${{\ \rm per\ cent}}$| and 1–2 |${{\ \rm per\ cent}}$|⁠ , respectively. Furthermore, the observed l  = 1 frequencies, which showed a mixed mode for the first time, were also fitted to the models. Information regarding the gravity and density of the helium core was obtained by examining the mixed modes. Moreover, new asteroseismic methods for determining the age of SG stars are developed for the first time in this study. [ABSTRACT FROM AUTHOR]

Published

2023

3. Asteroseismic analysis of 15 solar-like oscillating evolved stars.

Author

Çelik Orhan, Z, Yıldız, M, and Kayhan, C

Subjects

*STELLAR structure, *STELLAR evolution, *FREQUENCIES of oscillating systems, *STELLAR oscillations, *ASTEROSEISMOLOGY, *TELESCOPES, *SPACE telescopes

Abstract

Asteroseismology using space-based telescopes is vital to our understanding of stellar structure and evolution. CoRoT, Kepler , and TESS space telescopes have detected large numbers of solar-like oscillating evolved stars. Solar-like oscillation frequencies have an important role in the determination of fundamental stellar parameters; in the literature, the relations between the two is established by the so-called scaling relations. In this study, we analyse data obtained from the observation of 15 evolved solar-like oscillating stars using the Kepler and ground-based telescopes. The main purpose of the study is to determine very precisely the fundamental parameters of evolved stars by constructing interior models using asteroseismic parameters. We also fit the reference frequencies of models to the observational reference frequencies caused by the He  ii ionization zone. The 15 evolved stars are found to have masses and radii within ranges of 0.79–1.47 M⊙ and 1.60–3.15 R ⊙, respectively. Their model ages range from 2.19 to 12.75 Gyr. It is revealed that fitting reference frequencies typically increase the accuracy of asteroseismic radius, mass, and age. The typical uncertainties of mass and radius are ∼3–6 and ∼1–2 per cent, respectively. Accordingly, the differences between the model and literature ages are generally only a few Gyr. [ABSTRACT FROM AUTHOR]

Published

2021

4. Robust asteroseismic properties of the bright planet host HD 38529.

Author

Ball, Warrick H, Chaplin, William J, Nielsen, Martin B, González-Cuesta, Lucia, Mathur, Savita, Santos, Ângela R G, García, Rafael, Buzasi, Derek, Mosser, Benoît, Deal, Morgan, Stokholm, Amalie, Mosumgaard, Jakob Rørsted, Silva Aguirre, Victor, Nsamba, Benard, Campante, Tiago, Cunha, Margarida S, Ong, Joel, Basu, Sarbani, Örtel, Sibel, and Çelik Orhan, Z

Subjects

STELLAR oscillations, BROWN dwarf stars, OSCILLATIONS

Abstract

The Transiting Exoplanet Survey Satellite (TESS) is recording short-cadence, high duty-cycle timeseries across most of the sky, which presents the opportunity to detect and study oscillations in interesting stars, in particular planet hosts. We have detected and analysed solar-like oscillations in the bright G4 subgiant HD 38529, which hosts an inner, roughly Jupiter-mass planet on a |$14.3\, \mathrm{d}$| orbit and an outer, low-mass brown dwarf on a |$2136\, \mathrm{d}$| orbit. We combine results from multiple stellar modelling teams to produce robust asteroseismic estimates of the star's properties, including its mass |$M=1.48\pm 0.04\, \mathrm{M}_\odot {}$|⁠ , radius |$R=2.68\pm 0.03\, \mathrm{R}_\odot {}$|⁠ , and age |$t=3.07\pm 0.39\, \mathrm{Gyr}{}$|⁠. Our results confirm that HD 38529 has a mass near the higher end of the range that can be found in the literature and also demonstrate that precise stellar properties can be measured given shorter timeseries than produced by CoRoT, Kepler , or K2. [ABSTRACT FROM AUTHOR]

Published

2020

5. TESS asteroseismology of the known planet host star λ2 Fornacis.

Author

Nielsen, M. B., Ball, W. H., Standing, M. R., Triaud, A. H. M. J., Buzasi, D., Carboneau, L., Stassun, K. G., Kane, S. R., Chaplin, W. J., Bellinger, E. P., Mosser, B., Roxburgh, I. W., Çelik Orhan, Z., Yıldız, M., Örtel, S., Vrard, M., Mazumdar, A., Ranadive, P., Deal, M., and Davies, G. R.

Subjects

ASTEROSEISMOLOGY, STELLAR rotation, FREQUENCIES of oscillating systems, VELOCITY measurements, TIME series analysis

Abstract

Context. The Transiting Exoplanet Survey Satellite (TESS) is observing bright known planet-host stars across almost the entire sky. These stars have been subject to extensive ground-based observations, providing a large number of radial velocity measurements. Aims. The objective of this work is to use the new TESS photometric observations to characterize the star λ2 Fornacis, and following this to update the parameters of the orbiting planet λ2 For b. Methods. We measured the frequencies of the p-mode oscillations in λ2 For, and in combination with non-seismic parameters estimated the stellar fundamental properties using stellar models. Using the revised stellar properties and a time series of archival radial velocities from the UCLES, HIRES and HARPS instruments spanning almost 20 years, we refit the orbit of λ2 For b and searched the residual radial velocities for remaining variability. Results. We find that λ2 For has a mass of 1.16 ± 0.03 M⊙ and a radius of 1.63 ± 0.04 R⊙, with an age of 6.3 ± 0.9 Gyr. This and the updated radial velocity measurements suggest a mass of λ2 For b of 16.8−1.3+1.2M⊕ 16. 8 − 1.3 + 1.2 M ⊕ $ 16.8^{+1.2}_{-1.3}\,{{M}_\oplus} $ , which is ∼5M⊕ less than literature estimates. We also detect an additional periodicity at 33 days in the radial velocity measurements, which is likely due to the rotation of the host star. Conclusions. While previous literature estimates of the properties of λ2 For are ambiguous, the asteroseismic measurements place the star firmly at the early stage of its subgiant evolutionary phase. Typically only short time series of photometric data are available from TESS, but by using asteroseismology it is still possible to provide tight constraints on the properties of bright stars that until now have only been observed from the ground. This prompts a reexamination of archival radial velocity data that have been accumulated in the past few decades in order to update the characteristics of the planet hosting systems observed by TESS for which asteroseismology is possible. [ABSTRACT FROM AUTHOR]

Published

2020

6. Asteroseismic investigation of 20 planet and planet-candidate host stars.

Author

Kayhan, C, Yıldız, M, and Çelik Orhan, Z

Subjects

PLANETS, STARS, FREQUENCIES of oscillating systems, STELLAR oscillations, RED giants

Abstract

Planets and planet candidates are subjected to great investigation in recent years. In this study, we analyse 20 planet and planet-candidate host stars at different evolutionary phases. We construct stellar interior models of the host stars with the mesa e.volution code and obtain their fundamental parameters under influence of observational asteroseismic and non-asteroseismic constraints. Model mass range of the host stars is 0.74–1.55    |$\rm M_{\odot }$|⁠. The mean value of the so-called large separation between oscillation frequencies and its variation about the minima shows the diagnostic potential of asteroseismic properties. Comparison of variations of model and observed large separations versus the oscillation frequencies leads to inference of fundamental parameters of the host stars. Using these parameters, we revise orbital and fundamental parameters of 34 planets and four planet candidates. According to our findings, radius range of the planets is 0.35–16.50  |$\rm R_{{\oplus }}$|⁠. The maximum difference between the transit and revised radii occurs for Kepler-444b-f is about 25 per cent. [ABSTRACT FROM AUTHOR]

Published

2019

7. Fundamental properties of Kepler and CoRoT targets – IV. Masses and radii from frequencies of minimum Δν and their implications.

Author

Yıldız, M, Çelik Orhan, Z, and Kayhan, C

Subjects

*STELLAR oscillations, *FREQUENCIES of oscillating systems, *STELLAR mass, *RADIUS (Geometry), *COOL stars (Astronomy)

Abstract

Recently, by analysing the oscillation frequencies of 90 stars, Yıldız, Çelik Orhan & Kayhan have shown that the reference frequencies (νmin0, νmin1, and νmin2) derived from glitches due to He  ii ionization zone have very strong diagnostic potential for the determination of their effective temperatures. In this study, we continue to analyse the same stars and compute their mass, radius, and age from different scaling relations including relations based on νmin0, νmin1, and νmin2. For most of the stars, the masses computed using νmin0 and νmin1 are very close to each other. For 38 stars, the difference between these masses is less than 0.024 M |$\odot$| . The radii of these stars from νmin0 and νmin1 are even closer, with differences of less than 0.007 R |$\odot$| . These stars may be the most well known solar-like oscillating stars and deserve to be studied in detail. The asteroseismic expressions we derive for mass and radius show slight dependence on metallicity. We therefore develop a new method for computing initial metallicity from this surface metallicity by taking into account the effect of microscopic diffusion. The time dependence of initial metallicity shows some very interesting features that may be important for our understanding of chemical enrichment of Galactic Disc. According to our findings, every epoch of the disc has its own lowest and highest values for metallicity. It seems that rotational velocity is inversely proportional to 1/2 power of age as given by the Skumanich relation. [ABSTRACT FROM AUTHOR]

Published

2019

8. On the structure and evolution of planets and their host stars – effects of various heating mechanisms on the size of giant gas planets.

Author

Yıldız, M., Çelik Orhan, Z., Kayhan, C., and Turkoglu, G. E.

Subjects

*STELLAR evolution, *INTERIOR of stars, *STELLAR radiation, *PLANETARY mass, *DISSOCIATION (Chemistry)

Abstract

It is already stated in the previous studies that the radius of the giant planets is affected by stellar irradiation. The confirmed relation between radius and incident flux depends on planetary mass intervals. In this study, we show that there is a single relation between radius and irradiated energy per gram per second (l−), for all mass intervals. There is an extra increase in radius of planets if l− is higher than 1100 times energy received by the Earth (l⊕). This is likely due to dissociation of molecules. The tidal interaction as a heating mechanism is also considered and found that its maximum effect on the inflation of planets is about 15 per cent. We also compute age and heavy element abundances from the properties of host stars, given in the TEPCat catalogue (Southworth 2011). The metallicity given in the literature is as [Fe/H]. However, the most abundant element is oxygen, and there is a reverse relation between the observed abundances [Fe/H] and [O/Fe]. Therefore, we first compute [O/H] from [Fe/H] by using observed abundances, and then find heavy element abundance from [O/H]. We also develop a new method for age determination. Using the ages we find, we analyse variation of both radius and mass of the planets with respect to time, and estimate the initial mass of the planets from the relation we derive for the first time. According to our results, the highly irradiated gas giants lose 5 per cent of their mass in every 1 Gyr. [ABSTRACT FROM AUTHOR]

Published

2014

9. Fundamental properties of solar-like oscillating stars from frequencies of minimum Δν – I. Model computations for solar composition.

Author

Yıldız, M., Çelik Orhan, Z., Aksoy, Ç., and Ok, S.

Subjects

*STELLAR oscillations, *STELLAR evolution, *INTERIOR of stars, *ASTROPHYSICS, *STELLAR mass

Abstract

Low amplitude is the defining characteristic of solar-like oscillations. The space projects Kepler and CoRoT give us a great opportunity to successfully detect such oscillations in numerous targets. Achievements of asteroseismology depend on new discoveries of connections between the oscillation frequencies and stellar properties. In the previous studies, the frequency of the maximum amplitude and the large separation between frequencies were used for this purpose. In the present study, we confirm that the large separation between the frequencies has two minima at two different frequency values. These are the signatures of the He ii ionization zone, and as such have very strong diagnostic potential. We relate these minima to fundamental stellar properties such as mass, radius, luminosity, age and mass of convective zone. For mass, the relation is simply based on the ratio of the frequency of minimum Δν to the frequency of maximum amplitude. These frequency comparisons can be very precisely computed, and thus the mass and radius of a solar-like oscillating star can be determined to high precision. We also develop a new asteroseismic diagram which predicts structural and evolutionary properties of stars with such data. We derive expressions for mass, radius, effective temperature, luminosity and age in terms of purely asteroseismic quantities. For solar-like oscillating stars, we now will have five very important asteroseismic tools (two frequencies of minimum Δν, the frequency of maximum amplitude, and the large and small separations between the oscillation frequencies) to decipher properties of stellar interior astrophysics. [ABSTRACT FROM AUTHOR]

Published

2014