Kepler-46

Kepler-46
Observation data Epoch J2000 Equinox J2000
Artist's conception of the Kepler-46 system showing the two planets. Planet b transits its star, the same method by which it was detected.
Constellation	Lyra
Right ascension	19^h 17^m 4.449^s^[1]
Declination	42° 36′ 15.03″^[1]
Characteristics
Spectral type	Unknown
Apparent magnitude (H)	13.436^[1]
Apparent magnitude (K)	13.347^[1]
Astrometry

Distance	2795 ± 226 ly (857 ± 69 pc)
Absolute bolometric magnitude (M_bol)	5.18 (predicted)^{[note 1]}

Details

Mass	0.902 ± 0.04^[2] M_☉
Radius	0.94 ± 0.04^[2] R_☉
Temperature	5155 ± 105^[2] K
Metallicity [Fe/H]	0.41 ± 0.1^[2]^{[note 2]} dex
Age	9.9 ^+3.5_-3.1^[2] Gyr

Other designations
2MASS J19170449+4236150, KIC 7109675^[1]

Kepler-46, previously designated KOI-872, is a star located in the constellation Lyra. Observed since 2009 by the Kepler space observatory, it has since been found to possess a planetary system consisting of at least two planets and while it has a similar mass to the Sun (90%) it is significantly older at ten billion years.^[2]

Kepler-46 b (previously KOI-872.01), was the first planet discovered in the system. It was found through detailed analysis of Kepler space observatory data. An additional planet, Kepler-46 c, was discovered by an outside group using Kepler public data through analysis of transit timing variations. While only one additional planet was confirmed by the analysis, the study revealed the potential existence of either an unconfirmed planet KOI-872.03 (KOI-872 d). Validation by multiplicity method allowed to confirm the existence of this planet which was then renamed Kepler-46d.

Planetary system

Planet b is a superjovian gas giant with 6 times the mass of Jupiter. The second planet in the system was among the first to be discovered through the method of transit timing variations, and through its confirmation of KOI-872 c with a 99% confidence level has shown that the method of detection may be used to detect future extrasolar planets and, possibly, extrasolar moons.^[3] This second planet exerted a gravitational force on the first planet, orbiting its host star in just 34 days. While this usually occurs on an extremely regular schedule, additional planets within the system can disrupt the time of the transit, and these disruptions can indicate the presence of a planet, even if the disrupting planet does not pass in front of the host star itself.^[3]

The data show that Kepler-46 c is an approximately Saturn-mass object with an orbital period of 57 days.^[3] As the planet does not itself transit its host star, there is no way of knowing its size (probably a similar size to its sibling). The measurements also suggest the existence of another planet orbiting with a period of about 6.8 days, but this planet is unconfirmed.^[2]

The method in which the planet was detected is similar to the way that the planet Neptune was discovered, in which the newly discovered planet is known by its pull on another which is already known to exist.^[4]

The Kepler-46 planetary system^[2]
Companion (in order from star)	Mass	Semimajor axis (AU)	Orbital period (days)	Eccentricity	Inclination	Radius
b	<6 M_J	0.1967 ± 0.0029	33.60134 ± 0.00021	0.01 ± 0.01	—	0.812 ± 0.043 R_J
c	0.376 ± 0.023 M_J	0.2799 ± 0.0041	57.004 ^+0.091_-0.1	0.01 ± 0.01	—	—
d	—	0.068 ± 0.003	6.76671 ± 0.00013	—	—	0.1513 ± 0.0089 R_J

References

1 2 3 4 5 "Basic data: 2MASS J19170449+4236150". SIMBAD. University of Strasbourg. 2012. Retrieved May 16, 2012.
1 2 3 4 5 6 7 8 Schneider, Jean. "Notes for Star Kepler-46". Extrasolar Planets Encyclopaedia. Retrieved May 16, 2012.
1 2 3 Moskowitz, Clara (May 10, 2012). "Hidden Alien Planet Revealed by Its Own Gravity". Space.com. Space.com. Retrieved May 10, 2012.
↑ Crockett, Christopher (May 12, 2012). "New planet found in distant solar system by its tug on another world". EarthSky. Earthsky Communications. Retrieved May 19, 2012.

Notes

↑ Figure based on the following equations, which calculated bolometric (total) luminosity across all spectra based on effective temperature: $m_{\rm {star}}=m_{\rm {sun}}-2.5\log _{10}\left({L_{\rm {star}} \over L_{\odot }}\cdot \left({\frac {d_{\rm {sun}}}{d_{\rm {star}}}}\right)^{2}\right)$ (cf. Luminosity) and $M=m_{\rm {star}}-5((\log _{10}{D_{L}})-1)\!\,$ (cf. Absolute magnitude)
↑ This measurement indicates the log₁₀ of the relative abundance of iron in the measured star to that of the Sun.

Stars of Lyra

Bayer	α (Vega) β (Sheliak) γ (Sulafat) δ¹ δ² ε^{1, 2} (Double Double) ζ¹ ζ² η (Aladfar) θ ι κ λ μ (Alathfar) ν¹ ν²

Flamsteed	16 17 19

Variable	R (13) S T V W RR RV RZ TT TZ UZ XY AY CC CN CY DM EP EZ FL HK HP HR KX MV V344 V361 V404 V473 V477 V478 V533 V542 V543 V545 V550 V558

HR	6845 6847 6853 6901 6968 6984 6997 7016 7017 7019 7030 7033 7041 7043 7044 7064 7073 7081 7112 7115 7118 7132 7140 7146 7162 7181 7202 7204 7212 7237 7238 7244 7253 7272 7280 7284 7302 7338 7345 7346 7359 7376 7382

HD	177830 180314 181068

Gliese	Gliese 758 GJ 4063

Kepler	7 8 9 14 19 20 24 25 26 30 37 38 46 53 55 59 60 62 65 75 83 88 91 92 93 94 95 98 100 102 103 104 105 109 128 130 131 138 177 238 277 279 282 350 410 444

Other	GSC 02634-01087 GSC 02652-01324 2MASS 1835+3259 WASP-3 WASP-58 WISE 1828+2650

List

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