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Characterization of the exoplanet host stars • Properties of the host stars of exoplanets are derived from a combination of astrometric, photometric, and spectroscopic observations, interpreted primarily within the context of stellar evolutionary models Exoplanets Properties of the host stars Astrometry Photometry Spectroscopy Planets and Astrobiology (2015-2016) G. Vladilo Characterization of the host star Models of stellar structure and evolution • Exoplanets have been found around stars with different masses, at different stages of their evolution, and at different locations in the Galaxy 1 3 Astrometry and stellar distances Characterization of the exoplanet host stars • Astrometric measurements provide the database of the most accurate determinations of parallatic angles and stellar distances • The Hipparcos satellite provided 1 mas accuracy for about 1.2x105 stars • Motivations – A good knowledge of the properties of the stars hosting exoplanets is fundamental to improve the accuracy of exoplanet measurements – Accurate determination of stellar masses and radii are required to derive masses and radii of the planets detected with the Doppler and transit methods, respectively Accurate measurements of stellar distances are fundamental to calibrate stellar parameters – Stellar ages indicate the evolutionary state of the hosted planets, since the process of planetary formation takes place over shorter time scales than those of stellar evolution – The space frequency and intrinsic luminosity of stars of different spectral types governs the efficiency of exoplanet observational surveys Improvement in the knowledge of exoplanet host star distances by Hipparcos for the 100 brightest stars with exoplanets known with Doppler method in 2010. Left: ground based compilations of distances. Right: Hipparcos distances. 2 4 Astrometry and stellar distances Bolometric corrections Bolometric corrections are a function of the effective temperature, which governs the spectral energy distribution of the stellar emission • The near future: Gaia mission (ESA) – http://gaia.esa.int – Unbiased survey of 109 point-like Galactic sources (6-20 mag) – Astrometric precision, up to 10 μas for the brightest sources, in the range of a few tens μas for other sources – Intermediate resolution spectra for ~ 150 x 106 stars – Will greatly increase the accuracy of exoplanet host stars distances – Stars with distances larger than 50-100 pc will most greatly benefit with respect to the current measurements based on Hipparcos – Mission launched in 2013, nominal end foreseen in 2018 – First data releases start to be available; accurate catalogs will become available in the next years Bolometric corrections also depend on the stellar surface gravity, g (which is related to its intrinsic luminosity) and the abundance of metals, Z 5 7 Photometry and absolute luminosity Stellar radii Apparent and absolute magnitudes in a photometric band (e.g. the V band) Stellar radii can be determined by combining interferometric measurements of the angular size with accurate measurements of parallaxes apparent magnitude, mV absolute magnitude in the same band, MV (in absence of interstellar extinction) Bolometric magnitude (total energy integrated over all wavelengths) bolometric correction stellar luminosity The colour index is a photometric indicator of the spectral energy distribution 6 8 Hertzprung-Russel (HR) diagram Statistical properties of exoplanet host stars Fundamental tool to establish the evolutionary state and internal structure of the star Example of observational HR diagram • Exoplanet surveys provide the opportunity to search for correlations between the frequency of detected planets and the properties of the host stars • Trends between stellar and planet properties cast light on the process of planetary formation • Among the stellar properties investigated, we consider – Masses – Kinematic properties – Metallicities – Elemental abundance ratios Hipparcos based HR diagram for stars within 25 pc Filled circles: stars with planets (2003) 9 11 Number of detected exoplanets versus mass of the host star Hertzprung-Russel (HR) diagram Theoretical diagram: L* versus Teff Zero-age main sequences for low-mass stars versus Helium and “metal”abundances (Y and Z, respectively) Evolutionary tracks in HR diagrams are calculated for different masses and metallicities (stellar composition) 10 12 Mass of the planet versus mass of the host star Kinematic properties of exoplanet host stars Statistics of the planets detected with the Doppler method • The range of masses of stars with detected planets is not very broad • Masses of host stars are close to the solar mass Low-mass stars are less luminous and more difficult to observe High-mass stars are less perturbed by the planet Low-mass planets have been mostly discovered in stars less massive than the Sun High-mass planets are mostly discovered in stars more massive than the Sun • Stellar proper motions, together with distances and chemical abundances, cast light on the origin of stars with planetary systems • In principle, stars with and without planets might preferentially originate in different locations of the Galaxy • Several studies have investigated for possible systematic differences in kinematical properties between stars hosting planets and comparison sample of stars without planets • Most studies of this type find no significant differences between the kinematical properties of stars with and without planets • Some tentative difference is found when the stellar metallicity, in addition to the kinematics, is taken into account 13 Metallicity of the host star Distances and Teff of the host star • Distances – Most planets found between 10 and 1000 pc • Definition – The abundance by number of an element X relative to hydrogen (also called “absolute abundance”) is usually expressed in logarithmic units, relative to a reference value of solar abudance: Signal-to-noise ratio decreases with increasing distance to the star • Effective temperature – Most planets found in stars colder than the Sun Planet signal is stronger in stars of low mass (i.e., low effective temperature) However, low-mass stars tend to be excluded from surveys because of their faintness (and activity) 15 – For elements heavier than He, a measurement of stellar [X/H] is an indicator of stellar “metallicity” – The most classical indicator is [Fe/H], since iron lines are easy to measure in stellar spectra • The metallicity is an indicator of Galactic chemical evolution – Metals are produced by stellar nucleosynthesis and ejected in the interstellar medium – Stars born from the interstellar medium previously enriched by metals have a higher metallicity than stars of previous generations Teff,⨀ 14 16 Metallicity distribution of planet-hosting stars: experimental data Metallicity distribution: planet-hosting stars: versus comparison stars – The frequency of planet-hosting stars increases with metallicity and peaks at abundances higher than solar – Due to selection effects, the result is dominated by the statistics of giant planets • Statistical comparison between the two samples indicates that stars that host planets have a higher level of metallicity than stars without planets The selection of a statistical sample of comparison stars is not trivial Undetected low-mass planets could be present in the comparison sample 17 The trend with metallicity is observed for giant planets, but not for planets with lower mass 19 Metallicity distribution of planet-hosting stars: interpretation of the excess of high-metallicity planet hosts (Sousa et al. 2011) • The role of selection effects is not clear – The majority of the sample could be representative of a specific subset of the overall exoplanet population Giant planets • If selection bias is not important, three types of interpretation have been advanced – Primordial occurrence – Self-enrichment – Different Galactic origins Neptunian planets • Understanding the correct interpretation would cast light on the process of planetary formation - A larger statistics is required to understand if a trend exists for low-mass planets 18 20 Metallicity distribution of planet-hosting stars: interpretation of the excess of high-metallicity planet hosts Metallicity distribution of planet-hosting stars: interpretation • Different Galactic origins – According to this hypothesis, the giant planet occurrencemetallicity correlation is a dynamical manifestation related to the radial migration of stars in the Galactic disk – Giant planet formation is hypothesized to correlate with Galactocentric distance, rather being primarily linked to metallicity – Most metal-rich stars found in the solar neighbourhood are considered to have migrated from the inner Galactic disk, a few kpc away in the direction of the Galactic center, characterized by a higher metallicity – Planet formation could be related, not to metallicity, but to the presence of molecular hydrogen in the inner Galaxy – A larger reservoir of H2 is considered to improve the efficiency of star/planetary formation • Self-enrichment – In this interpretation, the high metallicity is a phenomenon restricted to the surface layers of the star, arising from the capture of metal-rich material, and the resulting ”pollution”of the outer convective envelope – The pollution could result from inward migration of a planet onto the star as a result of dynamical friction – Stars with protoplanetary disks would accrete more rocky material and hence their surface metallicity would rise – This hypothesis was advanced when the metallicity-occurrence trend was discovered, but is not supported by observational evidence 21 Metallicity distribution of planet-hosting stars: interpretation 23 Galactocentric metallicity gradients and stellar ages • Open squares: metallicity versus age of individual stars that are now found in the solar neighbourhood • Filled circles: mean metallicities as a function of age (Wielen et al. 1996) • Due to the presence of radial gradients of metallicity in the Galaxy, local stars of different metallicities may have originated at different Galactocentric distances, Ri • Dashed lines: lines of constant Galactocentric distance for their derived age-metallicity relation • Primordial occurrence – According to this hypothesis, the high metallicity observed in certain hosts is a bulk property of the star, and represents the original composition out of which the protostellar and protoplanetary disk formed – In this picture, the higher the metallicity of the primordial cloud, the higher the proportion of dust to gas in the protoplanetary disk – This facilitates condensation of solids and accelerates protoplanetary accretion before the gas disk is lost – At low metallicity, the protoplanetary material not used to build up giant planets would become available to accrete low-mass planets – This could explain why the mechanism is effective for giant planets, but apparently not for low-mass planets 22 24 Abundance ratios in stars with and without planets The α/Fe ratio in low-metallicity, planet hosting stars • The α/Fe ratio is a diagnostic tool of Galactic chemical evolution – The α elements are produced by α capture of atomic nuclei (e.g. Mg, Si, …) – The ratio α/Fe decreases in the course of chemical evolution due to the different time scales of the supernovae that produce mostly α elements (type II, fast) and of the supernovae that produce mostly iron-peak elements (type Ia, slow) – See course of Prof. F. Matteucci • The comparison of the α/Fe ratio in stars that host planets and stars that do not host planet may cast light on the efficiency of planetary formation at different values of α/Fe • Several studies have searched for systematic differences of element-toelement abundance ratios in stars with and without planets • With a few exceptions, most studies indicate that the relative abundances [X/Fe] are basically similar in stars with and without planets Open circles: planet host stars Crosses: comparison stars Dashed lines: solar abundances 25 Tentative evidence for enrichment of α elements in low-metallicity, planethosting stars (Adibekyan et al. 2012) Abundance ratios in stars with and without planets • 27 The lack of a significant trend between planet occurrence and element-to-element abundance ratios suggests that: If confirmed, it would suggest a dependence of planetary formation on the initial chemical composition of the protoplanetary cloud – the metal enrichment of planet hosting stars is primordial, rather than due to self-enrichment Black dots: stars without planetary companion – it is not necessary to invoke ecceptional events of chemical enrichment (such as the pollution by a nearby supernova) in order to trigger planetary formation 26 28