Making Chondrules by Splashing Molten Planetesimals

Ian S. Sanders; Edward R. D. Scott

doi:10.1017/9781108284073.014

14 - Making Chondrules by Splashing Molten Planetesimals

The Dirty Impact Plume Model

from Part II - Possible Chondrule-Forming Mechanisms

Published online by Cambridge University Press: 30 June 2018

Ian S. Sanders and

Edward R. D. Scott

Edited by

Sara S. Russell ,

Harold C. Connolly Jr. and

Alexander N. Krot

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Sara S. Russell: Affiliation:
Natural History Museum, London
Harold C. Connolly Jr.: Affiliation:
Rowan University, New Jersey
Alexander N. Krot: Affiliation:
University of Hawaii, Manoa

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Summary

The antiquity of iron meteorites and the inferred early intense heating by the decay of 26Al suggest that many planetesimals were molten beneath a thin insulating cap at the same time as chondrules were being made. As those planetesimals were colliding and merging, it seems inevitable that impact plumes of droplets from their liquid interiors would have been launched into space and cooled to form chondrules. We call the process splashing; it is quite distinct from making droplets by jetting during hypervelocity impacts. Evidence both for the existence of molten planetesimals, and for the cooling of chondrules within a plume setting, is strong and growing. Detailed petrographic and isotopic features of chondrules, particularly in carbonaceous chondrites (that probably formed beyond the orbit of Jupiter), suggest that the chondrule plume would have been ‘dirty’ and the otherwise uniform droplets would have been contaminated with earlier-formed dust and larger grains from a variety of sources. The contamination possibly accounts for relict grains, for the spread of oxygen isotopes along the primitive chondrule mineral (PCM) line in carbonaceous chondrites, and for the newly recognized nucleosynthetic isotopic complementarity between chondrules and matrix in Allende.

Type: Chapter
Information: Chondrules
Records of Protoplanetary Disk Processes
, pp. 361 - 374

DOI: https://doi.org/10.1017/9781108284073.014 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

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References

Alexander, C. M. O’D., Grossman, J. N., Ebel, D. S., and Ciesla, F. J. (2008). The formation conditions of chondrules and chondrites. Science, 320, 1617–1619.CrossRef Google Scholar PubMed

Asphaug, E., Jutzi, M., and Movshovitz, M. (2011). Chondrule formation during planetesimal accretion. Earth and Planetary Science Letters 308, 369–379.CrossRef Google Scholar

Bischoff, A., Wurm, G., Chaussidon, M., et al. (2017). The Allende multicompound chondrule (ACC) – Chondrule formation in a local super-dense region of the early solar system. Meteoritics and Planetary Science 52, 906–924.CrossRef Google Scholar

Budde, G., Kleine, T., Kruijer, T. S., Burkhardt, C., and Metzler, K. (2016a). Tungsten isotopic constraints on the age and origin of chondrules. Proceedings of the National Academy of Sciences 113, 2886–2891.CrossRef Google Scholar PubMed

Budde, G., Burkhardt, C., Brennecks, G. A., et al. (2016b). Molybdenum isotopic evidence for the origin of chondrules and a distinct genetic heritage of carbonaceous and non-carbonaceous meteorites. Earth and Planetary Science Letters 454, 293–303.CrossRef Google Scholar

Budde, G., Kruijer, T. S., and Kleine, T. (2018). Hafnium-tungsten chronology of CR chon- drites: Implications for the timescales of chondrule formation and the distribution of 26Al in the solar nebula. Geochimica et Cosmochimica Acta 222, 284–304.CrossRef Google Scholar

Chen, J. H., Papanastassiou, D. A., and Wasserburg, G. J. (1998). Re-Os systematics in chondrites and the fractionation of the platinum group elements in the early solar system. Geochimica et Cosmochimica Acta 62, 3379–3392.CrossRef Google Scholar

Connelly, J. N., Bizzarro, M., Krot, A. N., et al. (2012). The absolute chronology and thermal processing of solids in the solar protoplanetary disk. Science 338, 651–655.CrossRef Google Scholar PubMed

Dullemond, C. P., Stammler, S. M., and Johansen, A. (2014). Forming chondrules in impact splashes. I. Radiative cooling model. The Astrophysical Journal 794, 91.CrossRef Google Scholar

Dullemond, C. P., Harsono, D., Stammler, S. M., and Johansen, A. (2016). Forming Chondrules in Impact Splashes II Volatile Retention. The Astrophysical Journal, 832, article id. 91.CrossRef Google Scholar

Faure, F., Tissandier, L., Libourel, G., Romain, M., and Welsch, B. (2012). Origin of glass inclusions hosted in magnesian porphyritic olivine chondrules: Deciphering planetesimal compositions. Earth and Planetary Science Letters 319, 1–8.CrossRef Google Scholar

Faure, F., Tissandier, L., Florentin, L., and Devineau, K. (2017). A magmatic origin for silica-rich glass inclusions hosted in porphyritic magnesian olivines in chondrules: An experimental study. Geochimica et Cosmochimica Acta 204, 19–31.CrossRef Google Scholar

Florentin, L., Faure, F., Deloule, E., et al. (2017). Origin of Na in glass inclusions hosted in olivine from Allende CV3 and Jbilet Winselwan CM2: Implications for chondrule formation. Earth and Planetary Science Letters 474, 160–171.CrossRef Google Scholar

Gerber, S., Burkhardt, C., Budde, G., Metzler, K., and Kleine, T. (2017). Mixing and transport of dust in the early solar nebula as inferred from titanium isotope variations among chondrules. The Astrophysical Journal Letters, 841, L17.CrossRef Google Scholar

Grossman, J. N. (1988). Origin of chondrules. In Kerridge, J. F. and Matthews, M. S. (Eds.), Meteorites and the early Solar System, 680–696. Tucson, AZ: University of Arizona Press.Google Scholar

Grossman, L., Fedkin, A. V., and Simon, S. B. (2012). Formation of the first oxidized iron in the solar system. Meteoritics and Planetary Science 47, 2160–2169.CrossRef Google Scholar

Hevey, P. J., and Sanders, I. S. (2006). A model for planetesimal meltdown by ²⁶Al and its implications for meteorite parent bodies. Meteoritics and Planetary Science 41, 95–106.CrossRef Google Scholar

Hewins, R. H., Zanda, B., and Bendersky, C. (2012). Evaporation and recondensation of sodium in Semarkona Type II chondrules. Geochimica et Cosmochimica Acta 78, 1–17.CrossRef Google Scholar

Hutcheon, I. D., and Hutchison, R. (1989). Evidence from the Semarkona ordinary chondrite for ²⁶Al heating of small planets. Nature 337, 238–241.CrossRef Google Scholar

Johnson, B. C., Minton, D. A., Melosh, H. J., and Zuber, M. T. (2015). Impact jetting as the origin of chondrules. Nature 517, 339–341.CrossRef Google Scholar PubMed

Kennedy, A. K., Hutchison, R., Hutcheon, I. D., and Agrell, S. O. (1992). A unique high Mn/Fe microgabbro in the Parnallee (LL3) ordinary chondrite: Nebular mixture or planetary differentiate from a previously unrecognized planetary body? Earth and Planetary Science Letters 113, 191–205.CrossRef Google Scholar

Kiefer, W. S., and Mittlefehldt, D. W. (2017). Differentiation of asteroid 4 Vesta: Core formation by iron rain in a silicate magma ocean. Lunar and Planetary Science Conference XLVIII, abstract # 1798.Google Scholar

Kita, N. T., Nagahara, H., Tachibana, S., et al. (2010). High precision SIMS oxygen three isotope study of chondrules in LL3 chondrites: Role of ambient gas during chondrule formation. Geochimica et Cosmochimica Acta 74, 6610–6635.CrossRef Google Scholar

Kita, N. T., Tenner, T. J., Defouilloy, C., et al. (2015). Oxygen isotope systematics of chondrules in R3 clasts: A genetic link to ordinary chondrites. Lunar and Planetary Science Conference XLVI, abstract #2053.Google Scholar

Kleine, T., Mezger, K., Palme, H., Scherer, E., and Münker, C. (2005). Early core formation in asteroids and late accretion of chondrite parent bodies: Evidence from ¹⁸²Hf-¹⁸²W in CAIs, metal-rich chondrites, and iron meteorites. Geochimica et Cosmochimica Acta 69, 5805–5818.CrossRef Google Scholar

Kleine, T., and Wadhwa, M. (2017). Chronology of Planetesimal Differentiation. In Elkins-Tanton, L. T. and Weiss, B. P. (Eds.), Planetesimals: Early differentiation and Consequences for Planets, 224–245. Cambridge, UK: Cambridge University Press.CrossRef Google Scholar

Kruijer, T. S., Burkhardt, C., Budde, G., and Kleine, T. (2017). Age of Jupiter inferred from the distinct genetics and formation times of meteorites. Proceedings of the National Academy of Sciences 114, 6712–6716.CrossRef Google Scholar PubMed

Larsen, K. K., Trinquier, A., Paton, C., et al. (2011). Evidence for magnesium isotope heterogeneity in the solar protoplanetary disk. The Astrophysical Journal Letters 735, L37–L43.CrossRef Google Scholar

LaTourrette, T., and Wasserburg, G. J. (1998). Mg diffusion in anorthite: Implications for the formation of early solar system planetesimals. Earth and Planetary Science Letters 158, 91–108.CrossRef Google Scholar

Lichtenberg, T., Golabek, G. J., Gerya, T. V., and Meyer, M. R. (2016). The effects of short-lived radionuclides and porosity on the early thermo-mechanical evolution of planetesimals. Icarus 274, 350–365.CrossRef Google Scholar

Lichtenberg, T., Golabek, G. J., Dullemond, C. P., Schönbãchler, M., Gerya, T. V., and Meyer, M. B. (2018). Impact splash chondrule formation during planetesimal recycling. Icarus, 302, 27–43.CrossRef Google Scholar

Lugmair, G. W., and Shukolyukov, A. (2001). Early solar system events and timescales. Meteoritics and Planetary Science 36, 1017–1026.CrossRef Google Scholar

Metzler, K. (2012). Ultra-rapid chondrite formation by hot chondrule accretion? Evidence from unequilibrated ordinary chondrites. Meteoritics and Planetary Science 47, 2193–2217.CrossRef Google Scholar

Nagahara, H. (1981). Evidence for secondary origin of chondrules. Nature 292, 135–136.CrossRef Google Scholar

Nagashima, K., Krot, A. N., and Huss, G. R. (2015). Oxygen-isotope compositions of chondrule phenocrysts and matrix grains in Kakangari K-grouplet chondrite: Implication to a chondrule-matrix genetic relationship. Geochimica et Cosmochimica Acta 151, 49–67.CrossRef Google Scholar

Niemeyer, S. (1985). Systematics of Ti isotopes in carbonaceous chondrites. Geophysical Research Letters, 12, 733–736.CrossRef Google Scholar

Olsen, M. B., Wielandt, D., Schiller, M., Van Kooten, E. M. M. E., and Bizzarro, M. (2016). Magnesium and ⁵⁴Cr isotope compositions of carbonaceous chondrite chondrules – Insights into early disk processes. Geochimica et Cosmochimica Acta 191, 118–138.CrossRef Google Scholar PubMed

Palme, H., Hezel, D. C., and Ebel, D. S. (2015). The origin of chondrules: Constraints from matrix composition and matrix-chondrule complementarity. Earth and Planetary Science Letters 411, 11–19.CrossRef Google Scholar

Rambaldi, E. R. (1981). Relict grains in chondrules. Nature 293:558–561.CrossRef Google Scholar

Schiller, M., Connelly, J. N., Aslaug, C. G., Mikouchi, T., and Bizzarro, M. (2015). Early accretion of protoplanets inferred from a reduced inner solar system ²⁶Al inventory. Earth and Planetary Science Letters 420, 45–54.CrossRef Google Scholar PubMed

Sanders, I. S. (1996). A chondrule-forming scenario involving molten planetesimals. In Hewins, R. H., Jones, R. H., and Scott, E. R. D. (Eds.), Chondrules and the Protoplanetary Disk, 327–334. Cambridge, UK: Cambridge University Press.Google Scholar

Sanders, I. S., and Scott, E. R. D. (2012). The origin of chondrules and chondrites: Debris from low-velocity impacts between molten planetesimals? Meteoritics and Planetary Sciences 47, 2170–2192.CrossRef Google Scholar

Sanders, I. S., and Taylor, G. J. (2005). Implications of ²⁶Al in nebular dust: Formation of chondrules by disruption of molten planetesimals. In Krot, A. N., Scott, E. R. D., and Reipurth, B. (Eds.), Chondrites and the Protoplanetary Disk. Astronomical Society of the Pacific Conference Series 341, 821–838. San Francisco, CA: Astronomical Society of the Pacific.Google Scholar

Schrader, D. L., Nagashima, K., Fu, R. R., Davidson, J., and Ogliore, R. C. (2017). Evidence for chondrule migration from dusty olivine chondrules. Lunar and Planetary Science Conference XLVIII, abstract# 1271.Google Scholar

Soulié, C., Libourel, G., and Tissandier, L. (2017). Olivine dissolution in molten silicates: An experimental study with application to chondrule formation. Meteoritics and Planetary Sciences 52, 225–250.CrossRef Google Scholar

Tachibana, S., Nagahara, H., Mostefaoui, S., and Kita, N. T. (2003). Correlation between relative ages inferred from ²⁶Al and bulk compositions of ferromagnesian chondrules in least equilibrated ordinary chondrites. Meteoritics and Planetary Science 38, 939–962.CrossRef Google Scholar

Taylor, G. J., Scott, E. R. D., and Keil, K. (1983). Cosmic setting for chondrule formation. In King, E. A. (Ed.), Chondrules and their origins, 262–278. Houston, TX: Lunar and Planetary Institute.Google Scholar

Tenner, T. J., Nakashima, D. N., Ushikubo, T., Kita, N. T., and Weisberg, M. K. (2015). Oxygen isotope ratios of FeO-poor chondrules in CR3 chondrites: Influence of dust enrichment and H₂O during chondrule formation. Geochimica et Cosmochimica Acta 148, 228–250.CrossRef Google Scholar

Trinquier, A., Birck, J. -L., and Allègre, C. J. (2007). Widespread ⁵⁴Cr heterogeneity in the inner Solar System. The Astrophysical Journal 655, 1179–1185.CrossRef Google Scholar

Villeneuve, J., Chaussidon, M., and Libourel, G. (2012). Absence de relation entre les âges ²⁶Al de cristallisation des chondres et leurs compositions minéralogiques et chimiques. Comptes Rendus Geoscience 344, 423–431.CrossRef Google Scholar

Villeneuve, J., Libourel, G., and Soulié, C. (2015). Relationships between type I and type II chondrules: Implications on chondrule formation processes. Geochimica et Cosmochimica Acta 160, 277–305.CrossRef Google Scholar

Wänke, H., Dreibus, G., Jagoutz, E., Palme, H., and Rammensee, W. (1981). Chemistry of the Earth and the significance of primary and secondary objects for the formation of planets and meteorite parent bodies (abstract). Lunar and Planetary Science Conference XII, 1139–1141.Google Scholar

Wänke, H., Dreibus, G., and Jagoutz, E. (1984). Mantle chemistry and accretion history of the Earth. In Kroner, A., Hanson, G. N., and Goodwin, A. M. (Eds.), Archaean Geochemistry, 1–24. Berlin, Germany: Springer Verlag.Google Scholar

Warren, P. H. (2011). Stable-isotopic anomalies and the accretionary assemblage of the Earth and Mars: A subordinate role for carbonaceous chondrites. Earth and Planetary Science Letters 311, 93–100CrossRef Google Scholar

Wilson, L., and Keil, K. (2012). Volcanic activity on differentiated asteroids: A review and analysis. Chemie der Erde 72, 289–322.CrossRef Google Scholar

Zook, H. A. (1980). A new impact model for the generation of ordinary chondrites (abstract). Meteoritics 15, 390–391.Google Scholar

Zook, H. A. (1981). On a new model for the generation of chondrules (abstract). Lunar and Planetary Science Conference XII, 1242–1244.Google Scholar

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14 - Making Chondrules by Splashing Molten Planetesimals

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