Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications

William B. McKinnon; Xiaochen Mao; P. M. Schenk; K. N. Singer; S. J. Robbins; O. L. White; R. A. Beyer; S. B. Porter; J. T. Keane; D. T. Britt; J. R. Spencer; W. M. Grundy; J. M. Moore; S. A. Stern; H. A. Weaver; C. B. Olkin

doi:10.1029/2022GL098406

Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications

William B. McKinnon
, Xiaochen Mao
, P. M. Schenk
, K. N. Singer
, S. J. Robbins
, O. L. White
, R. A. Beyer
, S. B. Porter
, J. T. Keane
, D. T. Britt
, J. R. Spencer
, W. M. Grundy
, J. M. Moore
, S. A. Stern
, H. A. Weaver
, C. B. Olkin

Department of Earth & Planetary Sciences

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Evidence from Arrokoth and comets strongly suggests a very low density for this and similar small Kuiper belt objects. Plausible compositions imply high porosities, in excess of 70%, and low compaction crush strengths. If so, impact craters on Arrokoth (especially Sky, its largest) formed largely by compaction of pore space and material displacement. This is consistent with geological evidence from New Horizons imaging. High porosity reduces cratering efficiency in the gravity regime whereas compaction moves it toward crush strength scaling and increased efficiency. Compaction also guarantees that most impactor kinetic energy is taken up as waste heat near the impact point, with momentum transferred to the rest of the body by elastic waves only. Monte Carlo simulations of Sky-forming conditions indicate that the momentum imparted likely separated Arrokoth's two lobes, but displacement was limited by dissipation at the neck between them. Unusual strength properties are not required to preserve Arrokoth's bilobate configuration.

Original language	English
Article number	e2022GL098406
Journal	Geophysical Research Letters
Volume	49
Issue number	13
DOIs	https://doi.org/10.1029/2022GL098406
State	Published - Jul 16 2022

Keywords

Arrokoth
comets
compaction
impact cratering
Kuiper belt
porosity

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10.1029/2022GL098406

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McKinnon, W. B., Mao, X., Schenk, P. M., Singer, K. N., Robbins, S. J., White, O. L., Beyer, R. A., Porter, S. B., Keane, J. T., Britt, D. T., Spencer, J. R., Grundy, W. M., Moore, J. M., Stern, S. A., Weaver, H. A., & Olkin, C. B. (2022). Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications. Geophysical Research Letters, 49(13), Article e2022GL098406. https://doi.org/10.1029/2022GL098406

@article{4fc549ebc11842ebade446efb0d5b707,

title = "Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications",

abstract = "Evidence from Arrokoth and comets strongly suggests a very low density for this and similar small Kuiper belt objects. Plausible compositions imply high porosities, in excess of 70\%, and low compaction crush strengths. If so, impact craters on Arrokoth (especially Sky, its largest) formed largely by compaction of pore space and material displacement. This is consistent with geological evidence from New Horizons imaging. High porosity reduces cratering efficiency in the gravity regime whereas compaction moves it toward crush strength scaling and increased efficiency. Compaction also guarantees that most impactor kinetic energy is taken up as waste heat near the impact point, with momentum transferred to the rest of the body by elastic waves only. Monte Carlo simulations of Sky-forming conditions indicate that the momentum imparted likely separated Arrokoth's two lobes, but displacement was limited by dissipation at the neck between them. Unusual strength properties are not required to preserve Arrokoth's bilobate configuration.",

keywords = "Arrokoth, comets, compaction, impact cratering, Kuiper belt, porosity",

author = "McKinnon, \{William B.\} and Xiaochen Mao and Schenk, \{P. M.\} and Singer, \{K. N.\} and Robbins, \{S. J.\} and White, \{O. L.\} and Beyer, \{R. A.\} and Porter, \{S. B.\} and Keane, \{J. T.\} and Britt, \{D. T.\} and Spencer, \{J. R.\} and Grundy, \{W. M.\} and Moore, \{J. M.\} and Stern, \{S. A.\} and Weaver, \{H. A.\} and Olkin, \{C. B.\}",

year = "2022",

month = jul,

day = "16",

doi = "10.1029/2022GL098406",

language = "English",

volume = "49",

journal = "Geophysical Research Letters",

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McKinnon, WB, Mao, X, Schenk, PM, Singer, KN, Robbins, SJ, White, OL, Beyer, RA, Porter, SB, Keane, JT, Britt, DT, Spencer, JR, Grundy, WM, Moore, JM, Stern, SA, Weaver, HA & Olkin, CB 2022, 'Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications', Geophysical Research Letters, vol. 49, no. 13, e2022GL098406. https://doi.org/10.1029/2022GL098406

TY - JOUR

T1 - Snow Crash

T2 - Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications

AU - McKinnon, William B.

AU - Mao, Xiaochen

AU - Schenk, P. M.

AU - Singer, K. N.

AU - Robbins, S. J.

AU - White, O. L.

AU - Beyer, R. A.

AU - Porter, S. B.

AU - Keane, J. T.

AU - Britt, D. T.

AU - Spencer, J. R.

AU - Grundy, W. M.

AU - Moore, J. M.

AU - Stern, S. A.

AU - Weaver, H. A.

AU - Olkin, C. B.

PY - 2022/7/16

Y1 - 2022/7/16

N2 - Evidence from Arrokoth and comets strongly suggests a very low density for this and similar small Kuiper belt objects. Plausible compositions imply high porosities, in excess of 70%, and low compaction crush strengths. If so, impact craters on Arrokoth (especially Sky, its largest) formed largely by compaction of pore space and material displacement. This is consistent with geological evidence from New Horizons imaging. High porosity reduces cratering efficiency in the gravity regime whereas compaction moves it toward crush strength scaling and increased efficiency. Compaction also guarantees that most impactor kinetic energy is taken up as waste heat near the impact point, with momentum transferred to the rest of the body by elastic waves only. Monte Carlo simulations of Sky-forming conditions indicate that the momentum imparted likely separated Arrokoth's two lobes, but displacement was limited by dissipation at the neck between them. Unusual strength properties are not required to preserve Arrokoth's bilobate configuration.

AB - Evidence from Arrokoth and comets strongly suggests a very low density for this and similar small Kuiper belt objects. Plausible compositions imply high porosities, in excess of 70%, and low compaction crush strengths. If so, impact craters on Arrokoth (especially Sky, its largest) formed largely by compaction of pore space and material displacement. This is consistent with geological evidence from New Horizons imaging. High porosity reduces cratering efficiency in the gravity regime whereas compaction moves it toward crush strength scaling and increased efficiency. Compaction also guarantees that most impactor kinetic energy is taken up as waste heat near the impact point, with momentum transferred to the rest of the body by elastic waves only. Monte Carlo simulations of Sky-forming conditions indicate that the momentum imparted likely separated Arrokoth's two lobes, but displacement was limited by dissipation at the neck between them. Unusual strength properties are not required to preserve Arrokoth's bilobate configuration.

KW - Arrokoth

KW - comets

KW - compaction

KW - impact cratering

KW - Kuiper belt

KW - porosity

UR - https://www.scopus.com/pages/publications/85133922807

U2 - 10.1029/2022GL098406

DO - 10.1029/2022GL098406

M3 - Article

AN - SCOPUS:85133922807

SN - 0094-8276

VL - 49

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 13

M1 - e2022GL098406

ER -

Snow Crash: Compaction Craters on (486958) Arrokoth and Other Small KBOs, With Implications

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Keywords

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