Elliptical ejecta of asteroid Dimorphos is due to its surface curvature

Masatoshi Hirabayashi; Sabina D. Raducan; Jessica M. Sunshine; Tony L. Farnham; J. D.P. Deshapriya; Jian Yang Li; Gonzalo Tancredi; Steven R. Chesley; R. Terik Daly; Carolyn M. Ernst; Igor Gai; Pedro H. Hasselmann; Shantanu P. Naidu; Hari Nair; Eric E. Palmer; C. Dany Waller; Angelo Zinzi; Harrison F. Agrusa; Brent W. Barbee; Megan Bruck Syal; Gareth S. Collins; Thomas M. Davison; Mallory E. DeCoster; Martin Jutzi; Kathryn M. Kumamoto; Nicholas A. Moskovitz; Joshua R. Lyzhoft; Stephen R. Schwartz; Paul A. Abell; Olivier S. Barnouin; Nancy L. Chabot; Andrew F. Cheng; Elisabetta Dotto; Eugene G. Fahnestock; Patrick Michel; Derek C. Richardson; Andrew S. Rivkin; Angela M. Stickle; Cristina A. Thomas; Joel Beccarelli; John R. Brucato; Massimo Dall’Ora; Vincenzo Della Corte; Elena Mazzotta Epifani; Simone Ieva; Gabriele Impresario; Stavro Ivanovski; Alice Lucchetti; Dario Modenini; Maurizio Pajola; Pasquale Palumbo; Simone Pirrotta; Giovanni Poggiali; Alessandro Rossi; Paolo Tortora; Filippo Tusberti; Marco Zannoni; Giovanni Zanotti; Fabio Ferrari; David A. Glenar; Isabel Herreros; Seth A. Jacobson; Özgür Karatekin; Monica Lazzarin; Ramin Lolachi; Michael P. Lucas; Rahil Makadia; Francesco Marzari; Colby C. Merrill; Alessandra Migliorini; Ryota Nakano; Jens Ormö; Paul Sánchez; Cem Berk Senel; Stefania Soldini; Timothy J. Stubbs

doi:10.1038/s41467-025-56010-w

Elliptical ejecta of asteroid Dimorphos is due to its surface curvature

Masatoshi Hirabayashi, Sabina D. Raducan, Jessica M. Sunshine, Tony L. Farnham, J. D.P. Deshapriya, Jian Yang Li, Gonzalo Tancredi, Steven R. Chesley, R. Terik Daly, Carolyn M. Ernst, Igor Gai, Pedro H. Hasselmann, Shantanu P. Naidu, Hari Nair, Eric E. Palmer, C. Dany Waller, Angelo Zinzi, Harrison F. Agrusa, Brent W. Barbee, Megan Bruck SyalGareth S. Collins, Thomas M. Davison, Mallory E. DeCoster, Martin Jutzi, Kathryn M. Kumamoto, Nicholas A. Moskovitz, Joshua R. Lyzhoft, Stephen R. Schwartz, Paul A. Abell, Olivier S. Barnouin, Nancy L. Chabot, Andrew F. Cheng, Elisabetta Dotto, Eugene G. Fahnestock, Patrick Michel, Derek C. Richardson, Andrew S. Rivkin, Angela M. Stickle, Cristina A. Thomas, Joel Beccarelli, John R. Brucato, Massimo Dall’Ora, Vincenzo Della Corte, Elena Mazzotta Epifani, Simone Ieva, Gabriele Impresario, Stavro Ivanovski, Alice Lucchetti, Dario Modenini, Maurizio Pajola, Pasquale Palumbo, Simone Pirrotta, Giovanni Poggiali, Alessandro Rossi, Paolo Tortora, Filippo Tusberti, Marco Zannoni, Giovanni Zanotti, Fabio Ferrari, David A. Glenar, Isabel Herreros, Seth A. Jacobson, Özgür Karatekin, Monica Lazzarin, Ramin Lolachi, Michael P. Lucas, Rahil Makadia, Francesco Marzari, Colby C. Merrill, Alessandra Migliorini, Ryota Nakano, Jens Ormö, Paul Sánchez, Cem Berk Senel, Stefania Soldini, Timothy J. Stubbs

Astronomy and Planetary Sciences

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

2 Scopus citations

Abstract

Kinetic deflection is a planetary defense technique delivering spacecraft momentum to a small body to deviate its course from Earth. The deflection efficiency depends on the impactor and target. Among them, the contribution of global curvature was poorly understood. The ejecta plume created by NASA’s Double Asteroid Redirection Test impact on its target asteroid, Dimorphos, exhibited an elliptical shape almost aligned along its north-south direction. Here, we identify that this elliptical ejecta plume resulted from the target’s curvature, reducing the momentum transfer to 44 ± 10% along the orbit track compared to an equivalent impact on a flat target. We also find lower kinetic deflection of impacts on smaller near-Earth objects due to higher curvature. A solution to mitigate low deflection efficiency is to apply multiple low-energy impactors rather than a single high-energy impactor. Rapid reconnaissance to acquire a target’s properties before deflection enables determining the proper locations and timing of impacts.

Original language	English (US)
Article number	1602
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-56010-w
State	Published - Dec 2025

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-025-56010-w

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Hirabayashi, M., Raducan, S. D., Sunshine, J. M., Farnham, T. L., Deshapriya, J. D. P., Li, J. Y., Tancredi, G., Chesley, S. R., Daly, R. T., Ernst, C. M., Gai, I., Hasselmann, P. H., Naidu, S. P., Nair, H., Palmer, E. E., Waller, C. D., Zinzi, A., Agrusa, H. F., Barbee, B. W., ... Stubbs, T. J. (2025). Elliptical ejecta of asteroid Dimorphos is due to its surface curvature. Nature Communications, 16(1), Article 1602. https://doi.org/10.1038/s41467-025-56010-w

Hirabayashi, M, Raducan, SD, Sunshine, JM, Farnham, TL, Deshapriya, JDP, Li, JY, Tancredi, G, Chesley, SR, Daly, RT, Ernst, CM, Gai, I, Hasselmann, PH, Naidu, SP, Nair, H, Palmer, EE, Waller, CD, Zinzi, A, Agrusa, HF, Barbee, BW, Syal, MB, Collins, GS, Davison, TM, DeCoster, ME, Jutzi, M, Kumamoto, KM, Moskovitz, NA, Lyzhoft, JR, Schwartz, SR, Abell, PA, Barnouin, OS, Chabot, NL, Cheng, AF, Dotto, E, Fahnestock, EG, Michel, P, Richardson, DC, Rivkin, AS, Stickle, AM, Thomas, CA, Beccarelli, J, Brucato, JR, Dall’Ora, M, Corte, VD, Epifani, EM, Ieva, S, Impresario, G, Ivanovski, S, Lucchetti, A, Modenini, D, Pajola, M, Palumbo, P, Pirrotta, S, Poggiali, G, Rossi, A, Tortora, P, Tusberti, F, Zannoni, M, Zanotti, G, Ferrari, F, Glenar, DA, Herreros, I, Jacobson, SA, Karatekin, Ö, Lazzarin, M, Lolachi, R, Lucas, MP, Makadia, R, Marzari, F, Merrill, CC, Migliorini, A, Nakano, R, Ormö, J, Sánchez, P, Senel, CB, Soldini, S & Stubbs, TJ 2025, 'Elliptical ejecta of asteroid Dimorphos is due to its surface curvature', Nature Communications, vol. 16, no. 1, 1602. https://doi.org/10.1038/s41467-025-56010-w

@article{19ba2ae6038c454faff303bdc2f4dae8,

title = "Elliptical ejecta of asteroid Dimorphos is due to its surface curvature",

abstract = "Kinetic deflection is a planetary defense technique delivering spacecraft momentum to a small body to deviate its course from Earth. The deflection efficiency depends on the impactor and target. Among them, the contribution of global curvature was poorly understood. The ejecta plume created by NASA{\textquoteright}s Double Asteroid Redirection Test impact on its target asteroid, Dimorphos, exhibited an elliptical shape almost aligned along its north-south direction. Here, we identify that this elliptical ejecta plume resulted from the target{\textquoteright}s curvature, reducing the momentum transfer to 44 ± 10\% along the orbit track compared to an equivalent impact on a flat target. We also find lower kinetic deflection of impacts on smaller near-Earth objects due to higher curvature. A solution to mitigate low deflection efficiency is to apply multiple low-energy impactors rather than a single high-energy impactor. Rapid reconnaissance to acquire a target{\textquoteright}s properties before deflection enables determining the proper locations and timing of impacts.",

author = "Masatoshi Hirabayashi and Raducan, \{Sabina D.\} and Sunshine, \{Jessica M.\} and Farnham, \{Tony L.\} and Deshapriya, \{J. D.P.\} and Li, \{Jian Yang\} and Gonzalo Tancredi and Chesley, \{Steven R.\} and Daly, \{R. Terik\} and Ernst, \{Carolyn M.\} and Igor Gai and Hasselmann, \{Pedro H.\} and Naidu, \{Shantanu P.\} and Hari Nair and Palmer, \{Eric E.\} and Waller, \{C. Dany\} and Angelo Zinzi and Agrusa, \{Harrison F.\} and Barbee, \{Brent W.\} and Syal, \{Megan Bruck\} and Collins, \{Gareth S.\} and Davison, \{Thomas M.\} and DeCoster, \{Mallory E.\} and Martin Jutzi and Kumamoto, \{Kathryn M.\} and Moskovitz, \{Nicholas A.\} and Lyzhoft, \{Joshua R.\} and Schwartz, \{Stephen R.\} and Abell, \{Paul A.\} and Barnouin, \{Olivier S.\} and Chabot, \{Nancy L.\} and Cheng, \{Andrew F.\} and Elisabetta Dotto and Fahnestock, \{Eugene G.\} and Patrick Michel and Richardson, \{Derek C.\} and Rivkin, \{Andrew S.\} and Stickle, \{Angela M.\} and Thomas, \{Cristina A.\} and Joel Beccarelli and Brucato, \{John R.\} and Massimo Dall{\textquoteright}Ora and Corte, \{Vincenzo Della\} and Epifani, \{Elena Mazzotta\} and Simone Ieva and Gabriele Impresario and Stavro Ivanovski and Alice Lucchetti and Dario Modenini and Maurizio Pajola and Pasquale Palumbo and Simone Pirrotta and Giovanni Poggiali and Alessandro Rossi and Paolo Tortora and Filippo Tusberti and Marco Zannoni and Giovanni Zanotti and Fabio Ferrari and Glenar, \{David A.\} and Isabel Herreros and Jacobson, \{Seth A.\} and {\"O}zg{\"u}r Karatekin and Monica Lazzarin and Ramin Lolachi and Lucas, \{Michael P.\} and Rahil Makadia and Francesco Marzari and Merrill, \{Colby C.\} and Alessandra Migliorini and Ryota Nakano and Jens Orm{\"o} and Paul S{\'a}nchez and Senel, \{Cem Berk\} and Stefania Soldini and Stubbs, \{Timothy J.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-56010-w",

language = "English (US)",

volume = "16",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Nature Research",

number = "1",

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T1 - Elliptical ejecta of asteroid Dimorphos is due to its surface curvature

AU - Hirabayashi, Masatoshi

AU - Raducan, Sabina D.

AU - Sunshine, Jessica M.

AU - Farnham, Tony L.

AU - Deshapriya, J. D.P.

AU - Li, Jian Yang

AU - Tancredi, Gonzalo

AU - Chesley, Steven R.

AU - Daly, R. Terik

AU - Ernst, Carolyn M.

AU - Gai, Igor

AU - Hasselmann, Pedro H.

AU - Naidu, Shantanu P.

AU - Nair, Hari

AU - Palmer, Eric E.

AU - Waller, C. Dany

AU - Zinzi, Angelo

AU - Agrusa, Harrison F.

AU - Barbee, Brent W.

AU - Syal, Megan Bruck

AU - Collins, Gareth S.

AU - Davison, Thomas M.

AU - DeCoster, Mallory E.

AU - Jutzi, Martin

AU - Kumamoto, Kathryn M.

AU - Moskovitz, Nicholas A.

AU - Lyzhoft, Joshua R.

AU - Schwartz, Stephen R.

AU - Abell, Paul A.

AU - Barnouin, Olivier S.

AU - Chabot, Nancy L.

AU - Cheng, Andrew F.

AU - Dotto, Elisabetta

AU - Fahnestock, Eugene G.

AU - Michel, Patrick

AU - Richardson, Derek C.

AU - Rivkin, Andrew S.

AU - Stickle, Angela M.

AU - Thomas, Cristina A.

AU - Beccarelli, Joel

AU - Brucato, John R.

AU - Dall’Ora, Massimo

AU - Corte, Vincenzo Della

AU - Epifani, Elena Mazzotta

AU - Ieva, Simone

AU - Impresario, Gabriele

AU - Ivanovski, Stavro

AU - Lucchetti, Alice

AU - Modenini, Dario

AU - Pajola, Maurizio

AU - Palumbo, Pasquale

AU - Pirrotta, Simone

AU - Poggiali, Giovanni

AU - Rossi, Alessandro

AU - Tortora, Paolo

AU - Tusberti, Filippo

AU - Zannoni, Marco

AU - Zanotti, Giovanni

AU - Ferrari, Fabio

AU - Glenar, David A.

AU - Herreros, Isabel

AU - Jacobson, Seth A.

AU - Karatekin, Özgür

AU - Lazzarin, Monica

AU - Lolachi, Ramin

AU - Lucas, Michael P.

AU - Makadia, Rahil

AU - Marzari, Francesco

AU - Merrill, Colby C.

AU - Migliorini, Alessandra

AU - Nakano, Ryota

AU - Ormö, Jens

AU - Sánchez, Paul

AU - Senel, Cem Berk

AU - Soldini, Stefania

AU - Stubbs, Timothy J.

PY - 2025/12

Y1 - 2025/12

N2 - Kinetic deflection is a planetary defense technique delivering spacecraft momentum to a small body to deviate its course from Earth. The deflection efficiency depends on the impactor and target. Among them, the contribution of global curvature was poorly understood. The ejecta plume created by NASA’s Double Asteroid Redirection Test impact on its target asteroid, Dimorphos, exhibited an elliptical shape almost aligned along its north-south direction. Here, we identify that this elliptical ejecta plume resulted from the target’s curvature, reducing the momentum transfer to 44 ± 10% along the orbit track compared to an equivalent impact on a flat target. We also find lower kinetic deflection of impacts on smaller near-Earth objects due to higher curvature. A solution to mitigate low deflection efficiency is to apply multiple low-energy impactors rather than a single high-energy impactor. Rapid reconnaissance to acquire a target’s properties before deflection enables determining the proper locations and timing of impacts.

AB - Kinetic deflection is a planetary defense technique delivering spacecraft momentum to a small body to deviate its course from Earth. The deflection efficiency depends on the impactor and target. Among them, the contribution of global curvature was poorly understood. The ejecta plume created by NASA’s Double Asteroid Redirection Test impact on its target asteroid, Dimorphos, exhibited an elliptical shape almost aligned along its north-south direction. Here, we identify that this elliptical ejecta plume resulted from the target’s curvature, reducing the momentum transfer to 44 ± 10% along the orbit track compared to an equivalent impact on a flat target. We also find lower kinetic deflection of impacts on smaller near-Earth objects due to higher curvature. A solution to mitigate low deflection efficiency is to apply multiple low-energy impactors rather than a single high-energy impactor. Rapid reconnaissance to acquire a target’s properties before deflection enables determining the proper locations and timing of impacts.

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DO - 10.1038/s41467-025-56010-w

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SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1602

ER -

Elliptical ejecta of asteroid Dimorphos is due to its surface curvature

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