Low surface strength of the asteroid Bennu inferred from impact ejecta deposit

M. E. Perry; O. S. Barnouin; R. T. Daly; E. B. Bierhaus; R. L. Ballouz; K. J. Walsh; M. G. Daly; D. N. DellaGiustina; M. C. Nolan; J. P. Emery; M. M. Al Asad; C. L. Johnson; C. M. Ernst; E. R. Jawin; P. Michel; D. R. Golish; W. F. Bottke; J. A. Seabrook; D. S. Lauretta

doi:10.1038/s41561-022-00937-y

Low surface strength of the asteroid Bennu inferred from impact ejecta deposit

M. E. Perry, O. S. Barnouin, R. T. Daly, E. B. Bierhaus, R. L. Ballouz, K. J. Walsh, M. G. Daly, D. N. DellaGiustina, M. C. Nolan, J. P. Emery, M. M. Al Asad, C. L. Johnson, C. M. Ernst, E. R. Jawin, P. Michel, D. R. Golish, W. F. Bottke, J. A. Seabrook, D. S. Lauretta

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25 Scopus citations

Abstract

The surface strength of small rubble-pile asteroids, which are aggregates of unconsolidated material under microgravity, is poorly constrained but critical to understanding surface evolution and geologic history of the asteroid. Here we use images of an impact ejecta deposit and downslope avalanche adjacent to a 70-m-diameter impact crater on the rubble-pile asteroid (101955) Bennu to constrain the asteroid’s surface properties. We infer that the ejecta deposited near the crater must have been mobilized with velocities less than Bennu’s escape velocity (20 cm s^–1); such low velocities can be explained only if the effective strength of the local surface is exceedingly low, nominally ≤2 Pa. This value is four orders of magnitude below strength values commonly used for asteroid surfaces, but it is consistent with recent estimates of internal strength of rubble-pile asteroids and with the surface strength of another rubble-pile asteroid, Ryugu. We find a downslope avalanche indicating a surface composed of material readily mobilized by impacts and that has probably been renewed multiple times since Bennu’s initial assembly. Compared with stronger surfaces, very weak surfaces imply (1) more retention of material because of the low ejecta velocities and (2) lower crater-based age estimates—although the heterogeneous structure of rubble piles complicates interpretation.

Original language	English (US)
Pages (from-to)	447-452
Number of pages	6
Journal	Nature Geoscience
Volume	15
Issue number	6
DOIs	https://doi.org/10.1038/s41561-022-00937-y
State	Published - Jun 2022

ASJC Scopus subject areas

General Earth and Planetary Sciences

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10.1038/s41561-022-00937-y

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Perry, M. E., Barnouin, O. S., Daly, R. T., Bierhaus, E. B., Ballouz, R. L., Walsh, K. J., Daly, M. G., DellaGiustina, D. N., Nolan, M. C., Emery, J. P., Al Asad, M. M., Johnson, C. L., Ernst, C. M., Jawin, E. R., Michel, P., Golish, D. R., Bottke, W. F., Seabrook, J. A., & Lauretta, D. S. (2022). Low surface strength of the asteroid Bennu inferred from impact ejecta deposit. Nature Geoscience, 15(6), 447-452. https://doi.org/10.1038/s41561-022-00937-y

Perry, ME, Barnouin, OS, Daly, RT, Bierhaus, EB, Ballouz, RL, Walsh, KJ, Daly, MG, DellaGiustina, DN, Nolan, MC, Emery, JP, Al Asad, MM, Johnson, CL, Ernst, CM, Jawin, ER, Michel, P, Golish, DR, Bottke, WF, Seabrook, JA & Lauretta, DS 2022, 'Low surface strength of the asteroid Bennu inferred from impact ejecta deposit', Nature Geoscience, vol. 15, no. 6, pp. 447-452. https://doi.org/10.1038/s41561-022-00937-y

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title = "Low surface strength of the asteroid Bennu inferred from impact ejecta deposit",

abstract = "The surface strength of small rubble-pile asteroids, which are aggregates of unconsolidated material under microgravity, is poorly constrained but critical to understanding surface evolution and geologic history of the asteroid. Here we use images of an impact ejecta deposit and downslope avalanche adjacent to a 70-m-diameter impact crater on the rubble-pile asteroid (101955) Bennu to constrain the asteroid{\textquoteright}s surface properties. We infer that the ejecta deposited near the crater must have been mobilized with velocities less than Bennu{\textquoteright}s escape velocity (20 cm s–1); such low velocities can be explained only if the effective strength of the local surface is exceedingly low, nominally ≤2 Pa. This value is four orders of magnitude below strength values commonly used for asteroid surfaces, but it is consistent with recent estimates of internal strength of rubble-pile asteroids and with the surface strength of another rubble-pile asteroid, Ryugu. We find a downslope avalanche indicating a surface composed of material readily mobilized by impacts and that has probably been renewed multiple times since Bennu{\textquoteright}s initial assembly. Compared with stronger surfaces, very weak surfaces imply (1) more retention of material because of the low ejecta velocities and (2) lower crater-based age estimates—although the heterogeneous structure of rubble piles complicates interpretation.",

author = "Perry, {M. E.} and Barnouin, {O. S.} and Daly, {R. T.} and Bierhaus, {E. B.} and Ballouz, {R. L.} and Walsh, {K. J.} and Daly, {M. G.} and DellaGiustina, {D. N.} and Nolan, {M. C.} and Emery, {J. P.} and {Al Asad}, {M. M.} and Johnson, {C. L.} and Ernst, {C. M.} and Jawin, {E. R.} and P. Michel and Golish, {D. R.} and Bottke, {W. F.} and Seabrook, {J. A.} and Lauretta, {D. S.}",

note = "Funding Information: This material is based on work supported by NASA under contracts NNM10AA11C and NNG12FD66C, issued through the New Frontiers Program. The OSIRIS-REx Laser Altimeter and the Canadian authors were supported by the Canadian Space Agency. P.M. acknowledges funding support from the French space agency CNES, from the European Union{\textquoteright}s Horizon 2020 research and innovation programme under grant agreement no. 870377 (project NEO-MAPP) and from Academies of Excellence: Complex systems and Space, environment, risk, and resilience, part of the IDEX JEDI of the Universit{\'e} C{\^o}te d{\textquoteright}Azur. This work used the Small Body Mapping Tool ( http://sbmt.jhuapl.edu ). We are grateful to C. Wolner for her indispensable editing support and to the entire OSIRIS-REx Team of engineers, operators, scientists and administrators for making the encounter with Bennu possible. Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

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doi = "10.1038/s41561-022-00937-y",

language = "English (US)",

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T1 - Low surface strength of the asteroid Bennu inferred from impact ejecta deposit

AU - Perry, M. E.

AU - Barnouin, O. S.

AU - Daly, R. T.

AU - Bierhaus, E. B.

AU - Ballouz, R. L.

AU - Walsh, K. J.

AU - Daly, M. G.

AU - DellaGiustina, D. N.

AU - Nolan, M. C.

AU - Emery, J. P.

AU - Al Asad, M. M.

AU - Johnson, C. L.

AU - Ernst, C. M.

AU - Jawin, E. R.

AU - Michel, P.

AU - Golish, D. R.

AU - Bottke, W. F.

AU - Seabrook, J. A.

AU - Lauretta, D. S.

N1 - Funding Information: This material is based on work supported by NASA under contracts NNM10AA11C and NNG12FD66C, issued through the New Frontiers Program. The OSIRIS-REx Laser Altimeter and the Canadian authors were supported by the Canadian Space Agency. P.M. acknowledges funding support from the French space agency CNES, from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 870377 (project NEO-MAPP) and from Academies of Excellence: Complex systems and Space, environment, risk, and resilience, part of the IDEX JEDI of the Université Côte d’Azur. This work used the Small Body Mapping Tool ( http://sbmt.jhuapl.edu ). We are grateful to C. Wolner for her indispensable editing support and to the entire OSIRIS-REx Team of engineers, operators, scientists and administrators for making the encounter with Bennu possible. Publisher Copyright: © 2022, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2022/6

Y1 - 2022/6

N2 - The surface strength of small rubble-pile asteroids, which are aggregates of unconsolidated material under microgravity, is poorly constrained but critical to understanding surface evolution and geologic history of the asteroid. Here we use images of an impact ejecta deposit and downslope avalanche adjacent to a 70-m-diameter impact crater on the rubble-pile asteroid (101955) Bennu to constrain the asteroid’s surface properties. We infer that the ejecta deposited near the crater must have been mobilized with velocities less than Bennu’s escape velocity (20 cm s–1); such low velocities can be explained only if the effective strength of the local surface is exceedingly low, nominally ≤2 Pa. This value is four orders of magnitude below strength values commonly used for asteroid surfaces, but it is consistent with recent estimates of internal strength of rubble-pile asteroids and with the surface strength of another rubble-pile asteroid, Ryugu. We find a downslope avalanche indicating a surface composed of material readily mobilized by impacts and that has probably been renewed multiple times since Bennu’s initial assembly. Compared with stronger surfaces, very weak surfaces imply (1) more retention of material because of the low ejecta velocities and (2) lower crater-based age estimates—although the heterogeneous structure of rubble piles complicates interpretation.

AB - The surface strength of small rubble-pile asteroids, which are aggregates of unconsolidated material under microgravity, is poorly constrained but critical to understanding surface evolution and geologic history of the asteroid. Here we use images of an impact ejecta deposit and downslope avalanche adjacent to a 70-m-diameter impact crater on the rubble-pile asteroid (101955) Bennu to constrain the asteroid’s surface properties. We infer that the ejecta deposited near the crater must have been mobilized with velocities less than Bennu’s escape velocity (20 cm s–1); such low velocities can be explained only if the effective strength of the local surface is exceedingly low, nominally ≤2 Pa. This value is four orders of magnitude below strength values commonly used for asteroid surfaces, but it is consistent with recent estimates of internal strength of rubble-pile asteroids and with the surface strength of another rubble-pile asteroid, Ryugu. We find a downslope avalanche indicating a surface composed of material readily mobilized by impacts and that has probably been renewed multiple times since Bennu’s initial assembly. Compared with stronger surfaces, very weak surfaces imply (1) more retention of material because of the low ejecta velocities and (2) lower crater-based age estimates—although the heterogeneous structure of rubble piles complicates interpretation.

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Low surface strength of the asteroid Bennu inferred from impact ejecta deposit

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