# The shape of (7) Iris as evidence of an ancient large impact?

**Authors:** J. Hanu\v{s}, M. Marsset, P. Vernazza, M. Viikinkoski, A. Drouard, M., Bro\v{z}, B. Carry, R. Fetick, F. Marchis, L. Jorda, T. Fusco, M. Birlan, T., Santana-Ros, E. Podlewska-Gaca, E. Jehin, M. Ferrais, J. Grice, P. Bartczak,, J. Berthier, J. Castillo-Rogez, F. Cipriani, F. Colas, G. Dudzinski, C., Dumas, J. \v{D}urech, M. Kaasalainen, A. Kryszczynska, P. Lamy, H. Le, Coroller, A. Marciniak, T. Michalowski, P. Michel, M. Pajuelo, P. Tanga, F., Vachier, A. Vigan, O. Witasse, and B. Yang

arXiv: 1902.09242 · 2019-04-24

## TL;DR

This study used high-resolution imaging and shape modeling to analyze asteroid Iris, revealing its oblate spheroid shape, impact craters, and suggesting it experienced a significant ancient impact, providing insights into early solar system collisional history.

## Contribution

First detailed 3D shape reconstruction of asteroid Iris using disk-resolved images, linking its surface features to ancient impacts and formation processes.

## Key findings

- Iris has an oblate spheroid shape with a large equatorial depression.
- Identified eight impact craters with depth-to-diameter ratios similar to Vesta.
- Iris's bulk density matches LL ordinary chondrites, indicating its composition.

## Abstract

Asteroid (7) Iris is an ideal target for disk-resolved imaging owing to its brightness (V$\sim$7-8) and large angular size of 0.33 arcsec during its apparitions. Iris is believed to belong to the category of large unfragmented asteroids that avoided internal differentiation, implying that its current shape and topography may record the first few 100 Myr of the solar system's collisional evolution. We recovered information about the shape and surface topography of Iris from disk-resolved VLT/SPHERE/ZIMPOL images acquired in the frame of our ESO large program. We used the All-Data Asteroid Modeling (ADAM) shape reconstruction algorithm to model the 3D shape of Iris, using optical disk-integrated data and disk-resolved images from SPHERE as inputs. We analyzed the SPHERE images to infer the asteroid's global shape and the morphology of its main craters. We present the volume-equivalent diameter D$_{{\rm eq}}$=214$\pm$5 km, and bulk density $\rho$=2.7$\pm$0.3 g cm$^{-3}$ of Iris. Its shape appears to be consistent with that of an oblate spheroid with a large equatorial excavation. We identified eight putative surface features 20--40 km in diameter detected at several epochs, which we interpret as impact craters. Craters on Iris have depth-to-diameter ratios that are similar to those of analogous 10 km craters on Vesta. The bulk density of Iris is consistent with that of its meteoritic analog, namely LL ordinary chondrites. Considering the absence of a collisional family related to Iris and the number of large craters on its surface, we suggest that its equatorial depression may be the remnant of an ancient (at least 3 Gyr) impact. Iris's shape further opens the possibility that large planetesimals formed as almost perfect oblate spheroids. Finally, we attribute the difference in crater morphology between Iris and Vesta to their different surface gravities.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/1902.09242/full.md

## References

95 references — full list in the complete paper: https://tomesphere.com/paper/1902.09242/full.md

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Source: https://tomesphere.com/paper/1902.09242