Your search keyword '"Dante S. Lauretta"' showing total 8 results

1. Dynamical Evolution of Simulated Particles Ejected from Asteroid Bennu

Author

Jay W. McMahon, Daniel J. Scheeres, Steven R. Chesley, Andrew French, Daniel Brack, Davide Farnocchia, Yu Takahashi, Benjamin Rozitis, Pasquale Tricarico, Erwan Mazarico, Beau Bierhaus, Joshua P. Emery, Carl W. Hergenrother, and Dante S. Lauretta

Subjects

Space Sciences (General)

Abstract

In early 2019, the OSIRIS-REx spacecraft discovered small particles being ejected from the surface of the near-Earth asteroid Bennu. Although they were seen to be ejected at slow speeds, on the order of tens of cm/s, a number of particles were surprisingly seen to orbit for multiple revolutions and days, which requires a dynamical mechanism to quickly and substantially modify the orbit to prevent re-impact upon their first periapse passage. This paper demonstrates that, based on simulations constrained by the conditions of the observed events, the combined effects of gravity, solar radiation pressure, and thermal radiation pressure from Bennu can produce many sustained orbits for ejected particles. Furthermore, the simulated populations exhibit two interesting phenomena that could play an important role in the geophysical evolution of bodies such as Bennu. First, small particles (< 1 cm radius) are preferentially removed from the system, which could lead to a deficit of such particles on the surface. Second, re-impacting particles preferentially land near or on the equatorial bulge of Bennu. Over time, this can lead to crater in-filling and growth of the equatorial radius without requiring landslides.

Published

2020

2. Machine Learning Mid‐Infrared Spectral Models for Predicting Modal Mineralogy of CI/CM Chondritic Asteroids and Bennu

Author

Marina Gemma, Dante S. Lauretta, K. T. Howard, G. Kim, N. J. DiFrancesco, Hanna Nekvasil, A. D. Rogers, Alexander Kling, Timothy D. Glotch, V. E. Hamilton, P. R. Christensen, L. B. Breitenfeld, and Denton S. Ebel

Subjects

Geophysics, Modal, Space and Planetary Science, Geochemistry and Petrology, Asteroid, Earth and Planetary Sciences (miscellaneous), Mid infrared, Astronomy, Geology

Published

2021

3. Bennu's Natural Sample Delivery Mechanism: Estimating the Flux of Bennuid Meteors at Earth

Author

Robert Edward Melikyan, Carl Hergenrother, Dante S. Lauretta, Michael C. Nolan, Quanzhi Ye, Beth E. Clark, and Steven R. Chesley

Subjects

Geophysics, Meteoroid, Space and Planetary Science, Geochemistry and Petrology, Asteroid, Earth and Planetary Sciences (miscellaneous), Flux, Geology, Earth (classical element), Astrobiology

Abstract

NASA's OSIRIS-REx mission observed millimeter- to centimeter-scale pebbles being ejected from the surface of asteroid (101955) Bennu, indicating that Bennu is an active asteroid. About 30% of these...

Published

2021

4. Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set‐Up for Simulating the Near‐Surface Conditions of Airless Bodies

Author

Neil Bowles, Devin L. Schrader, T. Warren, S. B. Calcutt, V. E. Hamilton, A. Clack, Jon Temple, K. L. Donaldson Hanna, Dante S. Lauretta, and Timothy J. McCoy

Subjects

Atmospheres, 010504 meteorology & atmospheric sciences, Planetary Atmospheres, Clouds, and Hazes, Permafrost, Atmospheric Composition and Structure, Biogeosciences, 01 natural sciences, Meteorites and Tektites, Spectral line, Planetary Sciences: Solar System Objects, Physics and Chemistry of Materials, Earth and Planetary Sciences (miscellaneous), Planetary Sciences: Astrobiology, Permafrost, Cryosphere, and High‐latitude Processes, Planetary Atmospheres, Composition of Meteorites, Meteorite Mineralogy and Petrology, Asteroids, Characterization (materials science), Planetary Mineralogy and Petrology, Surfaces, Geophysics, Meteorite, Asteroid, Comets: Dust Tails and Trails, Bennu, Planetary Sciences: Comets and Small Bodies, airless bodies, Cryosphere, Composition, Research Article, spectroscopy, Materials science, Mineralogy, Planetary Geochemistry, Cryobiology, Geochemistry and Petrology, Chondrite, Comets, Emissivity, Spectroscopy, Planetary Sciences: Solid Surface Planets, Planetary Sciences: Fluid Planets, Mineralogy and Petrology, 0105 earth and related environmental sciences, Albedo, Geochemistry, Space and Planetary Science, thermal infrared, Other, laboratory, Natural Hazards

Abstract

We describe the capabilities, radiometric stability, and calibration of a custom vacuum environment chamber capable of simulating the near‐surface conditions of airless bodies. Here we demonstrate the collection of spectral measurements of a suite of fine particulate asteroid analogs made using the Planetary Analogue Surface Chamber for Asteroid and Lunar Environments (PASCALE) under conditions like those found on Earth and on airless bodies. The sample suite includes anhydrous and hydrated physical mixtures, and chondritic meteorites (CM, CI, CV, CR, and L5) previously characterized under Earth‐ and asteroid‐like conditions. And for the first time, we measure the terrestrial and extra‐terrestrial mineral end members used in the olivine‐ and phyllosilicate‐dominated physical mixtures under the same conditions as the mixtures and meteorites allowing us better understand how minerals combine spectrally when mixed intimately. Our measurements highlight the sensitivity of thermal infrared emissivity spectra to small amounts of low albedo materials and the composition of the sample materials. As the albedo of the sample decreases, we observe smaller differences between Earth‐ and asteroid‐like spectra, which results from a reduced thermal gradient in the upper hundreds of microns in the sample. These spectral measurements can be compared to thermal infrared emissivity spectra of asteroid (101955) Bennu's surface in regions where similarly fine particulate materials may be observed to infer surface compositions., Key Points Thermal infrared spectra of fine particulate minerals, physical mixtures of those minerals, and meteorites were measured under simulated Bennu conditionsComparisons of mineral, physical mixture, and meteorite spectra highlight the spectral behavior when materials are mixed in increasing complexityAs albedo decreases the spectral effects due to thermal gradients due to the vacuum environment of airless bodies are reduced

Published

2021

5. Global Patterns of Recent Mass Movement on Asteroid (101955) Bennu

Author

M. Al Asad, Daniella DellaGiustina, John Marshall, Daniel J. Scheeres, Kevin J. Walsh, E. B. Bierhaus, M. G. Daly, Olivier S. Barnouin, Jamie Molaro, Ronald-Louis Ballouz, R. T. Daly, Dante S. Lauretta, Harold C. Connolly, Carina Bennett, Erica Jawin, Timothy J. McCoy, Chloe B. Beddingfield, Michael C. Nolan, Hannah C.M. Susorney, H. L. Enos, and Hannah Kaplan

Subjects

Geophysics, Mass movement, Space and Planetary Science, Geochemistry and Petrology, Asteroid, Earth and Planetary Sciences (miscellaneous), Geology, Astrobiology

Published

2020

6. Photometry of Particles Ejected From Active Asteroid (101955) Bennu

Author

A. B. Davis, E. J. Lessac-Chenen, J. M. Leonard, S. S. Balram-Knutson, C. K. Maleszewski, R. Garcia, Steven R. Chesley, Daniella DellaGiustina, K. N. Burke, A. S. French, J. Y. Pelgrift, Eric Christensen, Andrew J. Liounis, Maurizio Pajola, K. Alkiek, Ellen S. Howell, Kris J. Becker, R. Melikyan, Beth E. Clark, Bashar Rizk, Coralie D. Adam, C. Drouet d'Aubigny, Carl Hergenrother, J. N. Kidd, Marina Brozovic, F. Shelly, Robert A. Jacobson, Dante S. Lauretta, Brent J. Bos, Davide Farnocchia, Ryan S. Park, Theodore Kareta, Michael C. Nolan, Jian-Yang Li, and S. Selznick

Subjects

Photometry (astronomy), Geophysics, Space and Planetary Science, Geochemistry and Petrology, Asteroid, Earth and Planetary Sciences (miscellaneous), Astronomy, Geology

Published

2020

7. Trajectory Estimation for Particles Observed in the Vicinity of (101955) Bennu

Author

C. W. V. Wolner, F. Shelly, J. Y. Pelgrift, Robert A. Jacobson, Jay W. McMahon, Daniel J. Scheeres, Eric Christensen, Carl Hergenrother, Coralie D. Adam, Steven R. Chesley, Marina Brozovic, Andrew J. Liounis, Davide Farnocchia, Michael C. Nolan, S. Selznick, Ben Rozitis, Brent J. Bos, A. S. French, Jamie Molaro, Y. Takahashi, E. J. Lessac-Chenen, Ryan S. Park, Dante S. Lauretta, A. B. Davis, Michael C. Moreau, David Vokrouhlický, Josh Emery, and J. M. Leonard

Subjects

Physics, 010504 meteorology & atmospheric sciences, Mass distribution, Spherical harmonics, 01 natural sciences, Ellipsoid, Computational physics, Geophysics, Gravitational field, Radiation pressure, Space and Planetary Science, Geochemistry and Petrology, Asteroid, Coefficient of restitution, Earth and Planetary Sciences (miscellaneous), SPHERES, 0105 earth and related environmental sciences

Abstract

We analyze the trajectories of 313 particles seen in the near‐Bennu environment between December 2018 and September 2019. Of these, 65% follow sub‐orbital trajectories, 20% undergo more than one orbital revolution around the asteroid, and 15% directly escape on hyperbolic trajectories. The median lifetime of these particles is ~6 h. The trajectories are sensitive to Bennu's gravitational field, which allows us to reliably estimate the spherical harmonic coefficients through degree 8 and to resolve nonuniform mass distribution through degree 3. The particles are perturbed by solar radiation pressure, enabling effective area‐to‐mass ratios to be estimated. By assuming that particles are oblate ellipsoids of revolution, and incorporating photometric measurements, we find a median axis ratio of 0.27 and diameters for equivalent‐volume spheres ranging from 0.22‐‐6.1 cm, with median 0.74 cm. Our size distribution agrees well with that predicted for fragmentation due to diurnal thermal cycling. Detailed models of known accelerations do not produce a match to the observed trajectories, so we also estimate empirical accelerations. These accelerations appear to be related to mismodeling of radiation pressure, but we cannot rule out contributions from mass loss. Most ejections take place at local solar times in the afternoon and evening (12:00‐‐24:00), although they occur at any time of day. We independently identify ten ejection events, some of which have previously been reported. We document a case where a particle ricocheted off the surface, revealing a coefficient of restitution 0.57±0.01 and demonstrating that some apparent ejections are not related to surface processes.

Published

2020

8. Thermal Fatigue as a Driving Mechanism for Activity on Asteroid Bennu

Author

Kevin J. Walsh, Carl Hergenrother, Ronald-Louis Ballouz, Christopher W. Haberle, William F. Bottke, Dante S. Lauretta, Jamie Molaro, Stephen R. Schwartz, Romy D. Hanna, H. J. Campins, and Steven R. Chesley

Subjects

Surface Materials and Properties, 010504 meteorology & atmospheric sciences, thermal fatigue, thermal breakdown, engineering.material, 01 natural sciences, Planetary Geochemistry, Stress (mechanics), thermal modeling, Planetary Sciences: Solar System Objects, Geochemistry and Petrology, Thermal, Earth and Planetary Sciences (miscellaneous), Planetary Sciences: Solid Surface Planets, Research Articles, Mineralogy and Petrology, 0105 earth and related environmental sciences, Diurnal temperature variation, Rubble, Fracture mechanics, Geophysics, exfoliation, Exfoliation joint, Asteroids, Planetary Mineralogy and Petrology, Surfaces, Exploration of the Activity of Asteroid (101955) Bennu, Geochemistry, Space and Planetary Science, Asteroid, engineering, Particle, Planetary Sciences: Comets and Small Bodies, Other, Erosion and Weathering, Natural Hazards, active asteroids, Geology, Composition, Research Article, thermal stress weathering

Abstract

Many boulders on (101955) Bennu, a near‐Earth rubble pile asteroid, show signs of in situ disaggregation and exfoliation, indicating that thermal fatigue plays an important role in its landscape evolution. Observations of particle ejections from its surface also show it to be an active asteroid, though the driving mechanism of these events is yet to be determined. Exfoliation has been shown to mobilize disaggregated particles in terrestrial environments, suggesting that it may be capable of ejecting material from Bennu's surface. We investigate the nature of thermal fatigue on the asteroid, and the efficacy of fatigue‐driven exfoliation as a mechanism for generating asteroid activity, by performing finite element modeling of stress fields induced in boulders from diurnal cycling. We develop a model to predict the spacing of exfoliation fractures and the number and speed of particles that may be ejected during exfoliation events. We find that crack spacing ranges from ~1 mm to 10 cm and disaggregated particles have ejection speeds up to ~2 m/s. Exfoliation events are most likely to occur in the late afternoon. These predictions are consistent with observed ejection events at Bennu and indicate that thermal fatigue is a viable mechanism for driving asteroid activity. Crack propagation rates and ejection speeds are greatest at perihelion when the diurnal temperature variation is largest, suggesting that events should be more energetic and more frequent when closer to the Sun. Annual thermal stresses that arise in large boulders may influence the spacing of exfoliation cracks or frequency of ejection events., Key Points We simulated stress fields in boulders to assess the nature and efficacy of thermal breakdown on Bennu, including by exfoliationOur model predicts that exfoliation is capable of ejecting centimeter‐scale particles from the asteroid at speeds of meters per secondThis mechanism is consistent with observations of particle ejection at Bennu and is a viable explanation for Bennu's activity

Published

2020