Episodes of particle ejection from the surface of the active asteroid (101955) Bennu

Bennu ejects material from its surface Most asteroids appear inert, but remote observations show that a small number experience mass loss from their surfaces. Lauretta and Hergenrother et al. describe close-range observations of mass loss on the near-Earth asteroid Bennu (see the Perspective by Agarwal). Shortly after arriving at Bennu, navigation cameras on the OSIRIS-REx (Origins, Spectral Interpretation, Resource Identification, and Security—Regolith Explorer) spacecraft detected objects 1 to 10 centimeters in diameter moving above the surface. Analysis of the objects' trajectories showed that they originated in discrete ejection events from otherwise unremarkable locations on Bennu. Some objects remained in orbit for several days, whereas others escaped into interplanetary space. The authors suggest multiple plausible mechanisms that could underlie this activity. Science, this issue p. eaay3544; see also p. 1192 The near-Earth asteroid Bennu ejects groups of solid objects from its surface in discrete events. INTRODUCTION Active asteroids are small bodies in the Solar System that show ongoing mass loss, such as the ejection of dust, which may be caused by large impacts, volatile release, or rotational acceleration. Studying them informs our understanding of the evolution and destruction of asteroids and the origin of volatile materials such as water on Earth. The OSIRIS-REx (Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer) spacecraft has rendezvoused with the near-Earth asteroid (101955) Bennu. The selection of Bennu as the OSIRIS-REx target was partially based on its spectral similarity to some active asteroids. Observations designed to detect mass loss at Bennu were conducted from Earth and during the spacecraft’s approach, but no signs of asteroid activity were found. However, when the spacecraft entered orbit in January 2019, we serendipitously observed particles in the vicinity of Bennu that had apparently been ejected from its surface. RATIONALE We analyzed the properties and behavior of particles ejected from Bennu to determine the possible mechanisms of ejection and provide understanding of the broader population of active asteroids. Images obtained by the spacecraft indicate multiple discrete ejection events with a range of energies and resultant particle trajectories. We characterized three large ejection events that respectively occurred on 6 January, 19 January, and 11 February 2019. Tracking of individual particles across multiple images by means of optical navigation techniques provided the initial conditions for orbit determination modeling. By combining these approaches, we estimated the locations and times of ejection events and determined initial velocity vectors of particles. We estimated the particle sizes and the minimum energies of the ejection events using a particle albedo and density consistent with observations of Bennu. RESULTS Particles with diameters from <1 to ~10 cm were ejected from Bennu at speeds ranging from ~0.05 to >3 m s–1. Estimated energies ranged from 270 mJ for the 6 January event to 8 mJ for the 11 February event. The three events arose from widely separated sites, which do not show any obvious geological distinction from the rest of Bennu’s surface. However, these events all occurred in the late afternoon, between about 15:00 and 18:00 local solar time. In addition to discrete ejection events, we detected a persistent background of particles in the Bennu environment. Some of these background particles have been observed to persist on temporary orbits that last several days—in one case, with a semimajor axis >1 km. The orbital characteristics of these gravitationally bound objects make it possible to determine the ratio of their cross-sectional area to their mass. Combined with their photometric phase functions, this information constrains the parameter space of the particles’ diameters, densities, and albedos. CONCLUSION Plausible mechanisms for the large ejection events include thermal fracturing, volatile release through dehydration of phyllosilicates, and meteoroid impacts. The late-afternoon timing of the events is consistent with any of these mechanisms. Bennu’s boulder geology indicates that thermal fracturing, perhaps enhanced by volatile release, could occur on the asteroid surface. Smaller events, especially those that occur on the night side of Bennu, could be attributable to reimpacting particles. Our observations classify Bennu as an active asteroid. Active asteroids are commonly identified by major mass loss events observable with telescopes, on scales much greater than we observed at Bennu. Our findings indicate that there is a continuum of mass loss event magnitudes among active asteroids. Schematic diagram of orbit determination model output for the 19 January 2019 particle ejection event from asteroid Bennu observed by the OSIRIS-REx spacecraft. Bennu is depicted in gray and has a diameter of ~500 m. OSIRIS-REx is indicated with the brown dot, ~2 km from Bennu’s center of mass; the cone represents the viewing angle. Blue arcs are particle trajectories, ending or with gaps where the trajectories pass into shadow. The Sun–angular momentum frame coordinates are shown at bottom right: x, solar vector; y, Bennu orbital direction; z, Bennu north. Active asteroids are those that show evidence of ongoing mass loss. We report repeated instances of particle ejection from the surface of (101955) Bennu, demonstrating that it is an active asteroid. The ejection events were imaged by the OSIRIS-REx (Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer) spacecraft. For the three largest observed events, we estimated the ejected particle velocities and sizes, event times, source regions, and energies. We also determined the trajectories and photometric properties of several gravitationally bound particles that orbited temporarily in the Bennu environment. We consider multiple hypotheses for the mechanisms that lead to particle ejection for the largest events, including rotational disruption, electrostatic lofting, ice sublimation, phyllosilicate dehydration, meteoroid impacts, thermal stress fracturing, and secondary impacts.

D. N. DellaGiustina | C. W. Hergenrother | B. Rizk | J. Licandro | D. S. Lauretta | J. N. Kidd | W. M. Owen | K. J. Becker | D. P. Glavin | J. M. Leonard | D. R. Golish | E. R. Jawin | P. G. Antreasian | M. C. Moreau | B. J. Bos | J. Y. Pelgrift | A. J. Liounis | D. Farnocchia | P. Jenniskens | M. Moreau | C. Maleszewski | D. Vokrouhlický | D. DellaGiustina | W. Bottke | C. d'Aubigny | B. Bos | D. Scheeres | P. Michel | B. Rozitis | J. Emery | G. Libourel | W. Owen | S. Chesley | D. Farnocchia | D. Lauretta | M. Daly | J. Licandro | H. Campins | C. Hartzell | J.‐Y. Li | R. Ballouz | F. Thuillet | K. Becker | P. Tricarico | Y. Takahashi | J. McMahon | A. Davis | E. Jawin | J. Leonard | P. Antreasian | J. Seabrook | M. A. Al Asad | M. Brozović | J. de León | J. Dworkin | D. Glavin | H. Connolly | R. Jacobson | D. Nelson | J. Molaro | D. Golish | S. Selznick | B. Rizk | C. D. Drouet d’Aubigny | C. Hergenrother | C. Bennett | H. Roper | A. Liounis | S. R. Chesley | P. Jenniskens | J. Pelgrift | C. Adam | J. Kidd | E. Lessac-Chenen | C. Manzoni | B. May | L. McCarthy | E. Sahr | C. Wolner | J.-Y. Li | C. A. Bennett | H. L. Roper | J. P. Dworkin | W. F. Bottke | H. C. Connolly | M. G. Daly | J. W. McMahon | D. J. Scheeres | B. Rozitis | J. P. Emery | D. Vokrouhlický | Y. Takahashi | P. Tricarico | R.-L. Ballouz | J. A. Seabrook | P. Michel | H. Campins | J. de León | E. J. Lessac-Chenen | D. S. Nelson | C. D. Adam | M. Al Asad | M. Brozović | A. B. Davis | C. Y. Drouet d’Aubigny | C. M. Hartzell | R. A. Jacobson | G. Libourel | C. K. Maleszewski | C. Manzoni | B. May | L. K. McCarthy | J. L. Molaro | E. M. Sahr | S. H. Selznick | F. Thuillet | C. W. V. Wolner | H. Campins | M. A. Asad | W. Bottke | M. Daly | S. Selznick | J. Leon | Marina Brozovic | D. DellaGiustina | K. Becker | Jian-Yang Li | B. Bos | Robert A. Jacobson | Josh Emery | Christine M. Hartzell | D. Nelson | William M. Owen

[1]  E. Wright,et al.  SPICE TOOLS SUPPORTING PLANETARY REMOTE SENSING , 2016 .

[2]  Modeling the coupled dynamics of an asteroid with surface boulder motion , 2019, Icarus.

[3]  남동석,et al.  III , 1751, Olav Audunssøn.

[4]  D. Jewitt,et al.  HUBBLE SPACE TELESCOPE INVESTIGATION OF MAIN-BELT COMET 133P/ELST-PIZARRO , 2014, 1402.5571.

[5]  D. R. Criswell,et al.  Surveyor observations of lunar horizon-glow , 1974 .

[6]  R. Tanner,et al.  OCAMS: The OSIRIS-REx Camera Suite , 2017, 1704.04531.

[7]  Steven R. Chesley,et al.  The Asteroid Identification Problem: III. Proposing Identifications , 2000 .

[8]  Jing Li,et al.  RECURRENT PERIHELION ACTIVITY IN (3200) PHAETHON , 2013, 1304.1430.

[9]  D. Scheeres,et al.  Detection of Rotational Acceleration of Bennu Using HST Light Curve Observations , 2019, Geophysical Research Letters.

[10]  Hugo Fechtig,et al.  Collisional balance of the meteoritic complex , 1985 .

[11]  M. C. Nolan,et al.  The dynamic geophysical environment of (101955) Bennu based on OSIRIS-REx measurements , 2019, Nature Astronomy.

[12]  D. Scheeres,et al.  Small body surface gravity fields via spherical harmonic expansions , 2014 .

[13]  F. Nieto,et al.  The Effect of Dry Grinding on Antigorite from Mulhacen, Spain , 1999 .

[14]  H. L. Enos,et al.  Overcoming the Challenges Associated with Image‐Based Mapping of Small Bodies in Preparation for the OSIRIS‐REx Mission to (101955) Bennu , 2018, Earth and Space Science.

[15]  Derek C. Richardson,et al.  An implementation of the soft-sphere discrete element method in a high-performance parallel gravity tree-code , 2012, Granular Matter.

[16]  G. Bierman Factorization methods for discrete sequential estimation , 1977 .

[17]  D. Scheeres,et al.  Exterior gravitation of a polyhedron derived and compared with harmonic and mascon gravitation representations of asteroid 4769 Castalia , 1996 .

[18]  R. Blackman Methods of orbit refinement , 1964 .

[19]  H. Keller,et al.  Local Manifestations of Cometary Activity , 2019, Space Science Reviews.

[20]  S. Drapatz,et al.  Theory of Shock-Wave Ionization upon High-Velocity Impact of Micrometeorites , 1974 .

[21]  P. Brown,et al.  Simultaneous radar and video meteors—II: Photometry and ionisation , 2013 .

[22]  S. Chesley,et al.  The Asteroid Identification Problem IV: Attributions , 2001 .

[23]  E. Gibson,et al.  Thermogravimetric-quadrupole mass-spectrometric analysis of geochemical samples , 1972 .

[24]  David Jewitt,et al.  The Active Asteroids , 2011 .

[25]  R. Kotulla,et al.  Episodically Active Asteroid 6478 Gault , 2019, The Astrophysical Journal.

[26]  M. K. Crombie,et al.  The Unexpected Surface of Asteroid (101955) Bennu , 2019, Nature.

[27]  Derek C. Richardson,et al.  Numerical modeling of lander interaction with a low-gravity asteroid regolith surface , 2018, Astronomy & Astrophysics.

[28]  J. Guinn,et al.  TOPEX/POSEIDON Operational Orbit Determination Results Using Global Positioning Satellites , 1994 .

[29]  Angular momentum drain - A mechanism for despinning asteroids , 1984 .

[30]  S. Green,et al.  Directional characteristics of thermal–infrared beaming from atmosphereless planetary surfaces – a new thermophysical model , 2011, 1211.1844.

[31]  Takuji Nishimura,et al.  Mersenne twister: a 623-dimensionally equidistributed uniform pseudo-random number generator , 1998, TOMC.

[32]  nasa,et al.  Limiting Future Collision Risk to Spacecraft: An Assessment of NASA's Meteoroid and Orbital Debris Programs , 2019 .

[33]  P. Michel,et al.  Thermal fatigue as the origin of regolith on small asteroids , 2014, Nature.

[34]  Jing Li,et al.  THE DUST TAIL OF ASTEROID (3200) PHAETHON , 2013, 1306.3741.

[35]  D. Jewitt,et al.  FAST ROTATION AND TRAILING FRAGMENTS OF THE ACTIVE ASTEROID P/2012 F5 (GIBBS) , 2015, 1503.05632.

[36]  D. Vokrouhlický,et al.  Orbit and bulk density of the OSIRIS-REx target Asteroid (101955) Bennu , 2014, 1402.5573.

[37]  T. J. McCoy,et al.  Craters, boulders and regolith of (101955) Bennu indicative of an old and dynamic surface , 2019, Nature Geoscience.

[38]  Jing Li,et al.  ACTIVITY IN GEMINID PARENT (3200) PHAETHON , 2010, 1009.2710.

[39]  J. Borovička,et al.  Properties of small meteoroids studied by meteor video observations , 2019, Astronomy & Astrophysics.

[40]  山田 雅哉 擬似乱数生成器 Mersenne Twisterについて , 2013 .

[41]  Attributions , 2019, Medaka.

[42]  Peter Jenniskens,et al.  CAMS: Cameras for Allsky Meteor Surveillance to establish minor meteor showers , 2011 .

[43]  M. K. Crombie,et al.  Evidence for widespread hydrated minerals on asteroid (101955) Bennu , 2019, Nature Astronomy.

[44]  Scott W. Lewis,et al.  Thermal influences on spontaneous rock dome exfoliation , 2018, Nature Communications.

[45]  On magnetic equilibria in barotropic stars , 2014, 1412.1524.

[46]  D. N. DellaGiustina,et al.  Properties of rubble-pile asteroid (101955) Bennu from OSIRIS-REx imaging and thermal analysis , 2019, Nature Astronomy.

[47]  G. Holzhausen Origin of sheet structure, 1. Morphology and boundary conditions , 1989 .

[48]  C. Hartzell Dynamics of 2D electrostatic dust levitation at asteroids , 2019, Icarus.

[49]  M. Horányi,et al.  Grain‐scale supercharging and breakdown on airless regoliths , 2016 .

[50]  T. D. Moyer Formulation for Observed and Computed Values of Deep Space Network Data Types for Navigation , 2003 .

[51]  S. Larson,et al.  Image enhancement techniques for quantitative investigations of morphological features in cometary comae: A comparative study , 2014, 1406.0033.

[52]  D R Golish,et al.  The operational environment and rotational acceleration of asteroid (101955) Bennu from OSIRIS-REx observations , 2019, Nature Communications.

[53]  M. K. Crombie,et al.  OSIRIS-REx: Sample Return from Asteroid (101955) Bennu , 2017, Space Science Reviews.

[54]  L. Keller,et al.  Microchemical and structural evidence for space weathering in soils from asteroid Itokawa , 2014, Earth, Planets and Space.

[55]  M. K. Crombie,et al.  Shape of (101955) Bennu indicative of a rubble pile with internal stiffness , 2019, Nature geoscience.

[56]  Kazuya Yoshida,et al.  Touchdown of the Hayabusa Spacecraft at the Muses Sea on Itokawa , 2006, Science.

[57]  H. Zook The state of meteoritic material on the moon , 1975 .

[58]  R. Srama,et al.  Space Weathering Induced Via Microparticle Impacts: 2. Dust Impact Simulation and Meteorite Target Analysis , 2019, Journal of Geophysical Research: Planets.

[59]  Doug Tody,et al.  The Iraf Data Reduction And Analysis System , 1986, Astronomical Telescopes and Instrumentation.

[60]  N. Schorghofer Predictions of depth-to-ice on asteroids based on an asynchronous model of temperature, impact stirring, and ice loss , 2016 .

[61]  The influence of rough surface thermal-infrared beaming on the Yarkovsky and YORP effects , 2012, 1203.1464.

[62]  D. Jewitt,et al.  HUBBLE SPACE TELESCOPE INVESTIGATION OF MAIN-BELT COMET 133P/ELST-PIZARRO , 2014, 1402.5571.

[63]  Jing Li,et al.  Resurrection of (3200) Phaethon in 2016 , 2016, 1611.07061.

[64]  Coralie D. Jackman,et al.  OPTICAL NAVIGATION CAPABILITIES FOR DEEP SPACE MISSIONS , 2013 .

[65]  William V. Boynton,et al.  The OSIRIS-REx Laser Altimeter (OLA) Investigation and Instrument , 2017 .

[66]  W. A. Joye,et al.  New Features of SAOImage DS9 , 2003 .

[67]  J. Biele,et al.  Numerical simulations of the contact between the lander MASCOT and a regolith-covered surface , 2017, Advances in Space Research.

[68]  M. Brozović,et al.  The Orbits of Jupiter’s Irregular Satellites , 2017 .

[69]  Vincent Holmes,et al.  VAPoR - Volatile Analysis by Pyrolysis of Regolith - an Instrument for In Situ Detection of Water, Noble Gases, and Organics on the Moon , 2010 .

[70]  R. Ballouz Numerical Simulations of Granular Physics in the Solar System , 2017 .

[71]  M. Horányi,et al.  Dust charging and transport on airless planetary bodies , 2016 .

[72]  Edgar L. Andreas,et al.  New estimates for the sublimation rate for ice on the Moon , 2007 .

[73]  J. Molaro,et al.  Thermally induced stresses in boulders on airless body surfaces, and implications for rock breakdown , 2017, 1703.03085.

[74]  D. Scheeres Orbital motion in strongly perturbed environments : applications to asteroid, comet and planetary satellite orbiters , 2012 .

[75]  F. Moreno,et al.  EARLY EVOLUTION OF DISRUPTED ASTEROID P/2016 G1 (PANSTARRS) , 2016, 1607.03375.

[76]  D. Jewitt,et al.  THE ACTIVE ASTEROIDS , 2011, 1112.5220.

[77]  Karri Muinonen,et al.  A three-parameter magnitude phase function for asteroids , 2010 .

[78]  D. Scheeres,et al.  The role of cohesive forces in particle launching on the Moon and asteroids , 2011 .

[79]  The influence of global self-heating on the Yarkovsky and YORP effects , 2012, 1304.7656.

[80]  Kenneth Getzandanner,et al.  OSIRIS-REx Flight Dynamics and Navigation Design , 2018 .

[81]  P. Buseck,et al.  Mineralogy of fine-grained rims in the alh 81002 cm chondrite , 2000 .

[82]  Richard P. Binzel,et al.  The OSIRIS‐REx target asteroid (101955) Bennu: Constraints on its physical, geological, and dynamical nature from astronomical observations , 2015 .

[83]  K. E. Gordon,et al.  Touch And Go Camera System (TAGCAMS) for the OSIRIS-REx Asteroid Sample Return Mission , 2018 .

[84]  野村栄一,et al.  2 , 1900, The Hatak Witches.

[85]  Evon M. O. Abu-Taieh,et al.  Comparative Study , 2020, Definitions.

[86]  Robert A. Werner,et al.  The gravitational potential of a homogeneous polyhedron or don't cut corners , 1994 .