本奴母小行星吸积物质的种类和来源

IF 14.3 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Nature Astronomy Pub Date : 2025-08-22 DOI:10.1038/s41550-025-02631-6

J. J. Barnes, A. N. Nguyen, F. A. J. Abernethy, K. Bajo, D. V. Bekaert, E. Bloch, G. A. Brennecka, H. Busemann, J. S. Cowpe, S. A. Crowther, M. Ek, L. J. Fawcett, M. A. Fehr, I. A. Franchi, E. Füri, J. D. Gilmour, M. M. Grady, R. C. Greenwood, P. Haenecour, N. Kawasaki, P. Koefoed, D. Krietsch, L. Le, K. M. Liszewska, C. Maden, J. Malley, Y. Marrocchi, B. Marty, L. A. E. Meyer, T. S. Peretyazhko, L. Piani, J. Render, S. S. Russell, M. Rüfenacht, N. Sakamoto, M. Schönbächler, Q. R. Shollenberger, L. Smith, K. Thomas-Keprta, A. B. Verchovsky, J. Villeneuve, K. Wang, K. C. Welten, J. Wimpenny, E. A. Worsham, H. Yurimoto, L. Zimmermann, X. Zhao, C. M. O’D. Alexander, M. Amini, A. Baczynski, P. Bland, L. E. Borg, R. Burgess, M. W. Caffee, L. C. Chaves, P. L. Clay, J. P. Dworkin, D. I. Foustoukos, D. P. Glavin, V. E. Hamilton, D. Hill, C. H. House, G. R. Huss, T. Ireland, C. E. Jilly, F. Jourdan, L. P. Keller, T. S. Kruijer, V. Lai, T. J. McCoy, K. Nagashima, K. Nishiizumi, R. Ogliore, I. J. Ong, S. M. Reddy, W. D. A. Rickard, S. Sandford, D. W. Saxey, N. Timms, D. Weis, Z. E. Wilbur, T. J. Zega, D. N. DellaGiustina, C. W. V. Wolner, H. C. Connolly, D. S. Lauretta

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引用次数: 0

摘要

太阳系中形成的第一批天体从恒星、太阳系前分子云和原行星盘中获取物质。没有经历行星分化的小行星保留了这些原始吸积物质的证据。然而，热液蚀变等地质过程可以极大地改变它们的总体矿物学、同位素组成和化学性质。在这里，我们分析了来自小行星Bennu的样品的元素和同位素组成，以揭示其母体吸积物质的来源和类型。我们发现，一些原始的吸积物质逃脱了发生在母小行星上的广泛的含水蚀变，包括来自古代恒星的太阳系前颗粒，来自外太阳系或分子云的有机物，在太阳附近形成的难熔固体，以及富含中子的Ti同位素的尘埃。我们发现Bennu的同位素异常有机质、无水硅酸盐、K和Zn的轻同位素比其最接近的成分对应物，小行星Ryugu和ivuna型（CI）碳质球粒陨石更丰富。我们认为Bennu， Ryugu和CI球粒陨石的母体是由外原行星盘中一个共同但空间和/或时间上不均匀的物质储层形成的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

The variety and origin of materials accreted by Bennu’s parent asteroid

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The variety and origin of materials accreted by Bennu’s parent asteroid

The first bodies to form in the Solar System acquired their materials from stars, the presolar molecular cloud and the protoplanetary disk. Asteroids that have not undergone planetary differentiation retain evidence of these primary accreted materials. However, geologic processes such as hydrothermal alteration can dramatically change their bulk mineralogy, isotopic compositions and chemistry. Here we analyse the elemental and isotopic compositions of samples from asteroid Bennu to uncover the sources and types of material accreted by its parent body. We show that some primary accreted materials escaped the extensive aqueous alteration that occurred on the parent asteroid, including presolar grains from ancient stars, organic matter from the outer Solar System or molecular cloud, refractory solids that formed close to the Sun, and dust enriched in neutron-rich Ti isotopes. We find Bennu to be richer in isotopically anomalous organic matter, anhydrous silicates, and light isotopes of K and Zn than its closest compositional counterparts, asteroid Ryugu and Ivuna-type (CI) carbonaceous chondrite meteorites. We propose that the parent bodies of Bennu, Ryugu and CI chondrites formed from a common but spatially and/or temporally heterogeneous reservoir of materials in the outer protoplanetary disk.

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来源期刊

Nature Astronomy Physics and Astronomy-Astronomy and Astrophysics

CiteScore

19.50

自引率

2.80%

发文量

252

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