HD 100546

HD 100546, also known as KR Muscae, is a pre-main sequence star of spectral type B8 to A0 located 353 light-years (108 parsecs) from Earth in the southern constellation of Musca. The star is surrounded by a circumstellar disk from a distance of 0.2 to 4 AU, and again from 13 AU out to a few hundred AU, with evidence for a protoplanet forming at a distance of around 47 AU.

Estimated to be less than 10 million years old, it belongs to Herbig Ae/Be stars, and also the nearest example to the Solar System.

Planetary system

The HD 100546 system as a whole has one confirmed protoplanet candidate and there is evidence for 1–2 others, thus it is considered an important evolutionary precursor to intermediate-mass stars with multiple super-jovian planets at moderate/wide separations like HR 8799. While other hypothetical planets have been claimed to exist around the star, none of the discoveries have been confirmed.

Planet b

In 2013, researchers reported that they had found what seems to be a planet in the process of being formed, embedded in the star's large disc of gas and dust. If confirmed, it would represent the first opportunity to study the early stages of planet formation observationally. The flux from HD 100546 b and its circumplanetary disk (CPD) are superimposed, leaving its properties such the radius and temperature thus very uncertain.

Various estimates for the mass of HD 100546 b has been varying between 1 and 25 M_J. Although standard hot-start models imply a mass of approximately 15 M_J, other models and HD 100546 b's H-band photometry implies masses below 10 M_J for a 1-million-years-old newly born planet or if made visible by its CPD, while older ages suggest higher masses.

More recently in 2019 an upper limit for the planetary mass was given to be as low as 1.65 M_J based on the relation between the planet, CPD, and circumstellar disk (CSD) masses derived from numerical simulation. The CPD has been assumed to be optically thin with derived upper mass and radius limits of 1.44 times as massive as Earth (M_E) and 0.44 astronomical unit (AU), while the mass of CSD was given to be 50 M_J. While gas-starved models are also still compatible, this would suggest that HD 100546 b is inconsistent with several planet accretion models.

Fitting a single temperature blackbody to the observed fluxes of the point source component gives a very large radius of 6.9+2.7
−2.9 times that of Jupiter (R_Jup) and an effective temperature of 932+193
−202 K for the emitting area surrounding the embedded protoplanet respectively. This large radius refers to the diffuse dust and gas envelope or debris disk surrounding the planet, not the planet itself; these estimates are mistakenly used as a single planetary radius and effective temperature for HD 100546 b by the NASA Exoplanet Archive. A best-fit luminosity was also found by the same study to be 2.3+0.6
−0.4×10⁻⁴ times as luminous as the Sun (L_☉).

Despite the uncertainty of the planet's properties, a 2017 study calculated HD 100546 b as a very highly reddened substellar object with a good-fit effective temperature of 2,630 K and a planetary mass and radius of 25 M_Jup and 3.4 R_Jup, making it still one of the largest exoplanets discovered by size. However, it has been predicted by planetary evolutionary theory that gas giants including hot Jupiters typically cannot exceed 2.2 R_J and that more massive gas giants would have lower radius at the time of their formation. This mass would put the planet beyond the border between a large planet and a brown dwarf.

Planet c

In April 2003, another planetary companion candidate was proposed and evidence was later gathered using the UVES echelle spectrograph at the VLT in Chile in 2005. This confirms other data indicating a planetary companion with a mass approximately 20 M_J and a distance of 6.5 AU from HD 100546, although further examination of the disk profile indicates it might be a more massive object such as a brown dwarf or more than one planet.

The same planetary companion, dubbed "HD 100546 c", was observed in 2014, and is calculated to have a mass estimated to be between 5 M_J and 20 M_J. With an estimated distance roughly 13 AU from HD 100546, circumstantial evidence suggests that HD 100546 c may be responsible for clearing out the inner disk cavity, although it would have been rapidly accreting gas, and thus it would be unusually bright. It was also expected to be surrounded by a circumplanetary disk of about 0.1 AU in radius. The planet is calculated to have an accretion rate up to 10⁻⁸ M_☉ per year assuming a planetary mass of 15 M_Jup, which would correspond to a planetary radius of 0.13 R_☉ based on evolutionary tracks. Thus, HD 100546 c is either in a relatively quiescent stage or its growth from accretion is at a low level or has already ceased. The presence of disturbance, possibly created by HD 100546 c, is also confirmed by the detection of sulphur monoxide, indicating a shockwaves propagating through the gas disk.

The position where HD 100546 c was detected was inside compared with the gap between the inner and outer disks, and outside compared with the central cavity, so the validity of the planet was shown from the characteristics of the star disk. There was a discrepancy with the discussion. This companion candidate has been contested, however, and it may be a weakly polarized disk feature instead.

Planet d

ALMA observations at 1.3 mm have revealed a point source at a position angle of 37° and a projected separation of 7.8 AU, it has a mass of 33 to 77 Jupiter masses which would make it a brown dwarf, which could represent an additional planetary candidate, hereafter HD 100546 d.

Hypothetical planets

A disturbance in disk may have been caused by a ~10 M_E planet completely embedded in the dust shroud.

Circumstellar disk

Coronagraphic optical observations with the Hubble Space Telescope show complex spiral patterns in the circumstellar disk. The causes of these structures remain uncertain, although spirals are consistent with the instabilities caused by forming planets. The disk colors are similar to those derived for Kuiper Belt objects, suggesting that the same weathering processes are at work in HD 100546. The disk is fairly flat, consistent with an advanced evolutionary state, and have a wide gap at 40–150 AU radii, possibly carved by an outer planet in the gap.

Spectroscopic analysis of mid-IR data taken from OSCIR on the 4 m Blanco Telescope at Cerro Tololo Inter-American Observatory indicates the presence of a small particles (10–18 μm) containing silicates. The material is found at distances out to 17 AU away from the star and has a temperature of approximately 227 K.

See also

• List of exoplanet extremes

Notes

References

Further reading

• Van Den Ancker, M. E.; The, P. S.; Tjin a Djie, H. R. E.; Catala, C.; De Winter, D.; Blondel, P. F. C.; Waters, L. B. F. M. (1997). "HIPPARCOS data on Herbig Ae/Be stars: An evolutionary scenario". Astronomy and Astrophysics. 324. Bibcode:1997A&A...324L..33V.
• Butler, R. P.; et al. (2006). "Catalog of Nearby Exoplanets". The Astrophysical Journal. 646 (1): 505–522. arXiv:astro-ph/0607493. Bibcode:2006ApJ...646..505B. doi:10.1086/504701. S2CID 119067572.
• Ecuvillon, A.; Israelian, G.; Pont, F.; Santos, N.; et al. (August 2006). "Kinematics of planet-host stars and their relation to dynamical streams in the solar neighbourhood". Astronomy and Astrophysics. 461 (171): 171–182. arXiv:astro-ph/0608669. Bibcode:2007A&A...461..171E. doi:10.1051/0004-6361:20065872. S2CID 16935788.
• Jones, B.; Sleep, P.; Underwood, D. (June 2006). "Habitability of known exoplanetary systems based on measured stellar properties". The Astrophysical Journal. 649 (1010): 1010–1019. arXiv:astro-ph/0603200. Bibcode:2006ApJ...649.1010J. doi:10.1086/506557. S2CID 119078585.
• Mandell, Avi M.; Raymond, Sean N.; Sigurdsson, Steinn (May 2007). "Formation of Earth-like Planets During and After Giant Planet Migration". The Astrophysical Journal. 660 (1): 823–844. arXiv:astro-ph/0701048. Bibcode:2007ApJ...660..823M. doi:10.1086/512759. S2CID 4812445.
• Marchi, S. (May 2007). "Extrasolar planet taxonomy: a new statistical approach". The Astrophysical Journal. 666 (1): 475–485. arXiv:0705.0910. Bibcode:2007ApJ...666..475M. doi:10.1086/519760. S2CID 13882139.
• Hedrick, C. H.; Doering, R.; Lee, K.-G.; Sosey, M.; et al. (December 2005). "The Circumstellar Dust Disk of HD 100546". Bulletin of the American Astronomical Society. 37 (4): 1167. Bibcode:2005AAS...207.1009H.

External links

• Astronomy picture of the day - May 2, 2001

1. Protoplanet
2. Musca
3. List of largest exoplanets
4. List of directly imaged exoplanets
5. Clathrate hydrate
6. List of stars with proplyds
7. Gas giant
8. Extraterrestrial liquid water
9. Circumplanetary disk
10. Herbig Ae/Be star
11. List of resolved circumstellar disks
12. List of exoplanets discovered in 2014
13. Gum catalog
14. List of brown dwarfs
15. HD 104237
16. Strategic Explorations of Exoplanets and Disks with Subaru
17. List of stars in Musca
18. List of minor planets: 100001–101000
19. Orders of magnitude (length)