# A common origin for dynamically associated near-Earth asteroid pairs

**Authors:** Nicholas Moskovitz, Petr Fatka, Davide Farnocchia, Maxime Devogele,, David Polishook, Cristina A. Thomas, Michael Mommert, Louis D. Avner, Richard, P. Binzel, Brian Burt, Eric Christensen, Francesca DeMeo, Mary Hinkle, Joseph, L. Hora, Mitchell Magnusson, Robert Matson, Michael Person, Brian Skiff,, Audrey Thirouin, David Trilling, Lawrence H. Wasserman, Mark Willman

arXiv: 1905.12058 · 2019-06-26

## TL;DR

This paper presents evidence for two genetically related near-Earth asteroid pairs, supporting their formation via YORP spin-up or binary dissociation, and highlights their significance for studying asteroid evolution.

## Contribution

It provides the first evidence of dynamically associated asteroid pairs in near-Earth space and estimates their ages, advancing understanding of asteroid formation and evolution.

## Key findings

- Two near-Earth asteroid pairs identified as genetically related.
- Both pairs are of volatile-poor spectral class.
- One pair is among the youngest known asteroid systems, <10 kyr old.

## Abstract

Though pairs of dynamically associated asteroids in the Main Belt have been identified and studied for over a decade, very few pair systems have been identified in the near-Earth asteroid population. We present data and analysis that supports the existence of two genetically related pairs in near-Earth space. The members of the individual systems, 2015 EE7 -- 2015 FP124 and 2017 SN16 -- 2018 RY7, are found to be of the same spectral taxonomic class, and both pairs are interpreted to have volatile-poor compositions. In conjunction with dynamical arguments, this suggests that these two systems formed via YORP spin-up and/or dissociation of a binary precursor. Backwards orbital integrations suggest a separation age of <10 kyr for the pair 2017 SN16 -- 2018 RY7, making these objects amongst the youngest multiple asteroid systems known to date. A unique separation age was not realized for 2015 EE7 -- 2015 FP124 due to large uncertainties associated with these objects' orbits. Determining the ages of such young pairs is of great value for testing models of space weathering and asteroid spin-state evolution. As the NEO catalog continues to grow with current and future discovery surveys, it is expected that more NEO pairs will be found, thus providing an ideal laboratory for studying time dependent evolutionary processes that are relevant to asteroids throughout the Solar System.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1905.12058/full.md

## References

78 references — full list in the complete paper: https://tomesphere.com/paper/1905.12058/full.md

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Source: https://tomesphere.com/paper/1905.12058