Photophoretic Separation of Metals and Silicates: The Formation of Mercury-Like Planets and Metal Depletion in Chondrites

Wurm, Gerhard; Trieloff, M.; Rauer, H.

doi:10.1088/0004-637x/769/1/78

Cited by 95 publications

(83 citation statements)

References 75 publications

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“…How robust is this conclusion that K2-106 b is metal rich? When we use models published by Fortney et al (2007) or Wurm et al (2013), we obtain the same results. Thus, regardless of which set of stellar parameters we use, whether we include the jitter term, and regardless of which models we use, in all cases we reach the conclusion that the iron core contains more than half of the mass of the planet.…”

Section: Discussionmentioning

confidence: 60%

“…Therefore it is reasonable to consider similar formation scenarios for K2-106 b and Mercury. In this respect, it is interesting to note that Wurm et al (2013) argued that the high iron abundance of Mercury is due to the photophoresis in the protoplanetary disk and not the result of a giant impact, as was previously thought. Photophoresis is a process in which iron and silicates are separated in the disk.…”

Section: Discussionmentioning

confidence: 70%

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K2-106, a system containing a metal-rich planet and a planet of lower density

Guenther

Barragán

Dai

et al. 2017

A&A

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Aims. Planets in the mass range from 2 to 15 M ⊕ are very diverse. Some of them have low densities, while others are very dense. By measuring the masses and radii, the mean densities, structure, and composition of the planets are constrained. These parameters also give us important information about their formation and evolution, and about possible processes for atmospheric loss. Methods. We determined the masses, radii, and mean densities for the two transiting planets orbiting K2-106. The inner planet has an ultra-short period of 0.57 days. The period of the outer planet is 13.3 days. . Conclusions. Since the system contains two planets of almost the same mass, but different distances from the host star, it is an excellent laboratory to study atmospheric escape. In agreement with the theory of atmospheric-loss processes, it is likely that the outer planet has a hydrogen-dominated atmosphere. The mass and radius of the inner planet is in agreement with theoretical models predicting an iron core containing 80 +20 −30 % of its mass. Such a high metal content is surprising, particularly given that the star has an ordinary (solar) metal abundance. We discuss various possible formation scenarios for this unusual planet.

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Section: Discussionmentioning

confidence: 60%

Section: Discussionmentioning

confidence: 70%

K2-106, a system containing a metal-rich planet and a planet of lower density

Guenther

Barragán

Dai

et al. 2017

A&A

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“…However, the local material available will not significantly change. Also, it is currently often argued that inner planetary systems are formed from material drifting inward (Boley & Ford 2013;Wurm et al 2013;Hu et al 2014). Inward drift is a classical mechanism for redistribution of matter (Weidenschilling 1977).…”

Section: Introductionmentioning

confidence: 99%

Is There a Temperature Limit in Planet Formation at 1000 K?

Demirci¹,

Teiser²,

Steinpilz³

et al. 2017

ApJ

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Dust drifting inward in protoplanetary disks is subject to increasing temperatures. In laboratory experiments, we tempered basaltic dust between 873 K and 1273 K and find that the dust grains change in size and composition. These modifications influence the outcome of self-consistent low speed aggregation experiments showing a transition temperature of 1000 K. Dust tempered at lower temperatures grows to a maximum aggregate size of 2.02 ± 0.06 mm, which is 1.49 ± 0.08 times the value for dust tempered at higher temperatures. A similar size ratio of 1.75 ± 0.16 results for a different set of collision velocities. This transition temperature is in agreement with orbit temperatures deduced for observed extrasolar planets. Most terrestrial planets are observed at positions equivalent to less than 1000 K. Dust aggregation on the millimeter-scale at elevated temperatures might therefore be a key factor for terrestrial planet formation.

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“…These exoplanets, with high densities and large sizes, are orbiting their stars at very close distances (Wurm et al. ; Nayakshin ). These super‐Mercury planets have an internal structure identical with Mercury.…”

Section: Introductionmentioning

confidence: 99%

“…In a recently proposed scenario (Wurm et al. ), the photophoretic sorting of metal and silicate phases has been invoked during the formation of Mercury. The photophoretic sorting occurs due to distinct thermal gradients within silicate and metallic dust grains in an optically thin protoplanetary disk (Beresnev et al.…”

Section: Introductionmentioning

confidence: 99%

Did ²⁶Al and impact‐induced heating differentiate Mercury?

Bhatia

Sahijpal

2016

Meteorit & Planetary Scien

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Numerical models dealing with the planetary scale differentiation of Mercury are presented with the short‐lived nuclide, 26Al, as the major heat source along with the impact‐induced heating during the accretion of planets. These two heat sources are considered to have caused differentiation of Mars, a planet with size comparable to Mercury. The chronological records and the thermal modeling of Mars indicate an early differentiation during the initial ~1 million years (Ma) of the formation of the solar system. We theorize that in case Mercury also accreted over an identical time scale, the two heat sources could have differentiated the planets. Although unlike Mars there is no chronological record of Mercury's differentiation, the proposed mechanism is worth investigation. We demonstrate distinct viable scenarios for a wide range of planetary compositions that could have produced the internal structure of Mercury as deduced by the MESSENGER mission, with a metallic iron (Fe‐Ni‐FeS) core of radius ~2000 km and a silicate mantle thickness of ~400 km. The initial compositions were derived from the enstatite and CB (Bencubbin) chondrites that were formed in the reducing environments of the early solar system. We have also considered distinct planetary accretion scenarios to understand their influence on thermal processing. The majority of our models would require impact‐induced mantle stripping of Mercury by hit and run mechanism with a protoplanet subsequent to its differentiation in order to produce the right size of mantle. However, this can be avoided if we increase the Fe‐Ni‐FeS contents to ~71% by weight. Finally, the models presented here can be used to understand the differentiation of Mercury‐like exoplanets and the planetary embryos of Venus and Earth.

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Photophoretic Separation of Metals and Silicates: The Formation of Mercury-Like Planets and Metal Depletion in Chondrites

Cited by 95 publications

References 75 publications

K2-106, a system containing a metal-rich planet and a planet of lower density

K2-106, a system containing a metal-rich planet and a planet of lower density

Is There a Temperature Limit in Planet Formation at 1000 K?

Did ²⁶Al and impact‐induced heating differentiate Mercury?

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Photophoretic Separation of Metals and Silicates: The Formation of Mercury-Like Planets and Metal Depletion in Chondrites

Cited by 95 publications

References 75 publications

K2-106, a system containing a metal-rich planet and a planet of lower density

K2-106, a system containing a metal-rich planet and a planet of lower density

Is There a Temperature Limit in Planet Formation at 1000 K?

Did 26Al and impact‐induced heating differentiate Mercury?

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Did ²⁶Al and impact‐induced heating differentiate Mercury?