Your search keyword '"Naidu, Shantanu P."' showing total 142 results

1. The Debiased Near-Earth Object Population from ATLAS Telescopes

Author

Deienno, Rogerio, Denneau, Larry, Nesvorný, David, Vokrouhlický, David, Bottke, William F., Jedicke, Robert, Naidu, Shantanu, Chesley, Steven R., Farnocchia, Davide, and Chodas, Paul W.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

This work is dedicated to debias the Near-Earth Objects (NEO) population based on observations from the Asteroid Terrestrial-impact Last Alert System (ATLAS) telescopes. We have applied similar methods used to develop the recently released NEO model generator (NEOMOD), once debiasing the NEO population using data from Catalina Sky Survey (CSS) G96 telescope. ATLAS is composed of four different telescopes. We first analyzed observational data from each of all four telescopes separately and later combined them. Our results highlight main differences between CSS and ATLAS, e.g., sky coverage and survey power at debiasing the NEO population. ATLAS has a much larger sky coverage than CSS, allowing it to find bright NEOs that would be constantly "hiding" from CSS. Consequently, ATLAS is more powerful than CSS at debiasing the NEO population for H $\lesssim$ 19. With its intrinsically greater sensitivity and emphasis on observing near opposition, CSS excels in the debiasing of smaller objects. ATLAS, as an all sky survey designed to find imminent hazardous objects, necessarily spends a significant fraction of time looking at places on the sky where objects do not appear, reducing its power for debiasing the population of small objects. We estimate a NEO population completeness of $\approx$ 88%$^{+3\%}_{-2\%}$ for H $<$ 17.75 and $\approx$ 36%$^{+1\%}_{-1\%}$ for H $<$ 22.25. Those numbers are similar to previous estimates (within error bars for H $<$ 17.75) from CSS, yet, around 3% and 8% smaller at their face values, respectively. We also confirm previous finding that the $\nu_6$ secular resonance is the main source of small and faint NEOs at H = 28, whereas the 3:1 mean motion resonance with Jupiter dominates for larger and brighter NEOs at H = 15., Comment: Accepted for publication in Icarus, 26 pages, 13 figures, 2 tables

Published

2024

2. An Earth Encounter As the Cause of Chaotic Dynamics in Binary Asteroid (35107) 1991VH

Author

Meyer, Alex J, Fuentes-Muñoz, Oscar, Gkolias, Ioannis, Tsiganis, Kleomenis, Pravec, Petr, Naidu, Shantanu, and Scheeres, Daniel J

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Among binary asteroids, (35107) 1991VH stands out as unique given the likely chaotic rotation within its secondary component. The source of this excited dynamical state is unknown. In this work we demonstrate that a past close encounter with Earth could have provided the necessary perturbation to allow the natural internal dynamics, characterized by spin-orbit coupling, to evolve the system into its current dynamical state. In this hypothesis, the secondary of 1991VH was previously in a classical 1:1 spin-orbit resonance with an orbit period likely between 28-35 hours before being perturbed by an Earth encounter within $\sim80,000$ km. We find if the energy dissipation within the secondary is relatively inefficient, this excited dynamical state could persist to today and produce the observed ground-based measurements. Coupled with the orbital history of 1991VH, we can then place a constraint on the tidal dissipation parameters of the secondary., Comment: Accepted for publication in PSJ

Published

2024

3. NEOMOD 3: The Debiased Size Distribution of Near Earth Objects

Author

Nesvorny, David, Vokrouhlicky, David, Shelly, Frank, Deienno, Rogerio, Bottke, William F., Fuls, Carson, Jedicke, Robert, Naidu, Shantanu, Chesley, Steven R., Chodas, Paul W., Farnocchia, Davide, and Delbo, Marco

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Our previous model (NEOMOD2) for the orbital and absolute magnitude distribution of Near Earth Objects (NEOs) was calibrated on the Catalina Sky Survey observations between 2013 and 2022. Here we extend NEOMOD2 to include visible albedo information from the Wide-Field Infrared Survey Explorer. The debiased albedo distribution of NEOs can be approximated by the sum of two Rayleigh distributions with the scale parameters p_V,dark=0.03 and p_V,bright=0.17. We find evidence for smaller NEOs having (on average) higher albedos than larger NEOs; this is likely a consequence of the size-dependent sampling of different main belt sources. These inferences and the absolute magnitude distribution from NEOMOD2 are used to construct the debiased size distribution of NEOs. We estimate 830+/-60 NEOs with diameters D>1 km and 20,000+/-2,000 NEOs with D>140 m. The new model, NEOMOD3, is available via the NEOMOD Simulator -- an easy-to-operate code that can be used to generate user-defined samples (orbits, sizes and albedos) from the model., Comment: Icarus, in press

Published

2024

4. Dimorphos orbit determination from mutual events photometry

Author

Scheirich, Peter, Pravec, Petr, Meyer, Alex J., Agrusa, Harrison F., Richardson, Derek C., Chesley, Steven R., Naidu, Shantanu P., Thomas, Cristina, and Moskovitz, Nicholas A.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The NASA Double Asteroid Redirection Test (DART) spacecraft successfully impacted the Didymos-Dimorphos binary asteroid system on 2022 September 26 UTC. We provide an update to its pre-impact mutual orbit and estimate the post-impact physical and orbital parameters, derived using ground-based photometric observations taken from July 2022 to February 2023. We found that the total change of the orbital period was $-33.240 \pm 0.072$ min. (all uncertainties are 3$\sigma$). We obtained the eccentricity of the post-impact orbit to be $0.028 \pm 0.016$ and the apsidal precession rate of $7.3 \pm 2.0$ deg./day from the impact to 2022 December 2. The data taken later in December to February suggest that the eccentricity dropped close to zero or the orbit became chaotic approximately 70 days after the impact. Most of the period change took place immediately after the impact but in a few weeks following the impact it was followed by additional change of $-27^{+19}_{-58}$ seconds or $-19 \pm 18$ seconds (the two values depend on the approach we used to describe the evolution of the orbital period after the impact -- an exponentially decreasing angular acceleration or an assumption of a constant orbital period, which changed abruptly some time after the impact, respectively). We estimate the pre-impact Dimorphos-Didymos size ratio was $0.223 \pm 0.012$ and the post-impact is $0.202 \pm 0.018$, which indicates a marginally significant reduction of Dimorphos' volume by ($9 \pm 9) \%$ as the result of the impact., Comment: 31 pages, 7 figures

Published

2024

5. NEOMOD 2: An Updated Model of Near-Earth Objects from a Decade of Catalina Sky Survey Observations

Author

Nesvorny, David, Vokrouhlicky, David, Shelly, Frank, Deienno, Rogerio, Bottke, William F., Christensen, Eric, Jedicke, Robert, Naidu, Shantanu, Chesley, Steven R., Chodas, Paul W., Farnocchia, Davide, and Granvik, Mikael

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Catalina Sky Survey (CSS) is a major survey of Near-Earth Objects (NEOs). In a recent work, we used CSS observations from 2005-2012 to develop a new population model of NEOs (NEOMOD). CSS's G96 telescope was upgraded in 2016 and detected over 10,000 unique NEOs since then. Here we characterize the NEO detection efficiency of G96 and use G96's NEO detections from 2013-2022 to update NEOMOD. This resolves previous model inconsistencies related to the population of large NEOs. We estimate there are 936+/-29 NEOs with absolute magnitude H<17.75 (diameter D>1 km for the reference albedo p_V=0.14). The slope of the NEO size distribution for H=25-28 is found to be relatively shallow (cumulative index 2.6) and the number of H<28 NEOs (D>9 m) is determined to be (1.20+/-0.04)x10^7. Small NEOs have a different orbital distribution and higher impact probabilities than large NEOs. We estimate 0.034+/-0.002 impacts of H<28 NEOs on the Earth per year, which is near the low end of the impact flux range inferred from atmospheric bolide observations. Relative to a model where all NEOs are delivered directly from the main belt, the population of small NEOs detected by G96 shows an excess of low-eccentricity orbits with a=1--1.6 au that appears to increase with H. We suggest that the population of very small NEOs is boosted by tidal disruption of large NEOs during close encounters to the terrestrial planets. When the effect of tidal disruption is (approximately) accounted for in the model, we estimate 0.06+/-0.01 impacts of H<28 NEOs on the Earth per year, which is more in line with the bolide data., Comment: Icarus, in press. arXiv admin note: text overlap with arXiv:2306.09521

Published

2023

6. Photometry of the Didymos system across the DART impact apparition

Author

Moskovitz, Nicholas, Thomas, Cristina, Pravec, Petr, Lister, Tim, Polakis, Tom, Osip, David, Kareta, Theodore, Rożek, Agata, Chesley, Steven R., Naidu, Shantanu P., Scheirich, Peter, Ryan, William, Ryan, Eileen, Skiff, Brian, Snodgrass, Colin, Knight, Matthew M., Rivkin, Andrew S., Chabot, Nancy L., Ayvazian, Vova, Belskaya, Irina, Benkhaldoun, Zouhair, Berteşteanu, Daniel N., Bonavita, Mariangela, Bressi, Terrence H., Brucker, Melissa J., Burgdorf, Martin J., Burkhonov, Otabek, Burt, Brian, Contreras, Carlos, Chatelain, Joseph, Choi, Young-Jun, Daily, Matthew, de León, Julia, Ergashev, Kamoliddin, Farnham, Tony, Fatka, Petr, Ferrais, Marin, Geier, Stefan, Gomez, Edward, Greenstreet, Sarah, Gröller, Hannes, Hergenrother, Carl, Holt, Carrie, Hornoch, Kamil, Husárik, Marek, Inasaridze, Raguli, Jehin, Emmanuel, Khalouei, Elahe, Eluo, Jean-Baptiste Kikwaya, Kim, Myung-Jin, Krugly, Yurij, Kučáková, Hana, Kušnirák, Peter, Larsen, Jeffrey A., Lee, Hee-Jae, Lejoly, Cassandra, Licandro, Javier, Longa-Peña, Penélope, Mastaler, Ronald A., McCully, Curtis, Moon, Hong-Kyu, Morrell, Nidia, Nath, Arushi, Oszkiewicz, Dagmara, Parrott, Daniel, Phillips, Liz, Popescu, Marcel M., Pray, Donald, Prodan, George Pantelimon, Rabus, Markus, Read, Michael T., Reva, Inna, Roark, Vernon, Santana-Ros, Toni, Scotti, James V., Tatara, Taiyo, Thirouin, Audrey, Tholen, David, Troianskyi, Volodymyr, Tubbiolo, Andrew F., and Villa, Katelyn

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

On 26 September 2022, the Double Asteroid Redirection Test (DART) spacecraft impacted Dimorphos, the satellite of binary near-Earth asteroid (65803) Didymos. This demonstrated the efficacy of a kinetic impactor for planetary defense by changing the orbital period of Dimorphos by 33 minutes (Thomas et al. 2023). Measuring the period change relied heavily on a coordinated campaign of lightcurve photometry designed to detect mutual events (occultations and eclipses) as a direct probe of the satellite's orbital period. A total of 28 telescopes contributed 224 individual lightcurves during the impact apparition from July 2022 to February 2023. We focus here on decomposable lightcurves, i.e. those from which mutual events could be extracted. We describe our process of lightcurve decomposition and use that to release the full data set for future analysis. We leverage these data to place constraints on the post-impact evolution of ejecta. The measured depths of mutual events relative to models showed that the ejecta became optically thin within the first ~1 day after impact, and then faded with a decay time of about 25 days. The bulk magnitude of the system showed that ejecta no longer contributed measurable brightness enhancement after about 20 days post-impact. This bulk photometric behavior was not well represented by an HG photometric model. An HG1G2 model did fit the data well across a wide range of phase angles. Lastly, we note the presence of an ejecta tail through at least March 2023. Its persistence implied ongoing escape of ejecta from the system many months after DART impact., Comment: 52 pages, 5 tables, 9 figures, accepted to PSJ

Published

2023

7. The Perturbed Full Two-Body Problem: Application to Post-DART Didymos

Author

Meyer, Alex J., Agrusa, Harrison F., Richardson, Derek C., Daly, R. Terik, Fuentes-Muñoz, Oscar, Hirabayashi, Masatoshi, Michel, Patrick, Merrill, Colby C., Nakano, Ryota, Cheng, Andrew F., Barbee, Brent, Barnouin, Olivier S., Chesley, Steven R., Ernst, Carolyn M., Gkolias, Ioannis, Moskovitz, Nicholas A., Naidu, Shantanu P., Pravec, Petr, Scheirich, Petr, Thomas, Cristina A., Tsiganis, Kleomenis, and Scheeres, Daniel J.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

With the successful impact of the NASA DART spacecraft in the Didymos-Dimorphos binary asteroid system, we provide an initial analysis of the post-impact perturbed binary asteroid dynamics. To compare our simulation results with observations, we introduce a set of "observable elements" calculated using only the physical separation of the binary asteroid, rather than traditional Keplerian elements. Using numerical methods that treat the fully spin-orbit-coupled dynamics, we estimate the system's mass and the impact-induced changes in orbital velocity, semimajor axis, and eccentricity. We find that the changes to the mutual orbit depend strongly on the separation distance between Didymos and Dimorphos at the time of impact. If Dimorphos enters a tumbling state after the impact, this may be observable through changes in the system's eccentricity and orbit period. We also find that any DART-induced reshaping of Dimorphos would generally reduce the required change in orbital velocity to achieve the measured post-impact orbit period and will be assessed by the ESA Hera mission in 2027., Comment: Accepted for publication in PSJ

Published

2023

8. NEOMOD: A New Orbital Distribution Model for Near Earth Objects

Author

Nesvorny, David, Deienno, Rogerio, Bottke, William F., Jedicke, Robert, Naidu, Shantanu, Chesley, Steven R., Chodas, Paul W., Granvik, Mikael, Vokrouhlicky, David, Broz, Miroslav, Morbidelli, Alessandro, Christensen, Eric, and Bolin, Bryce T.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Near Earth Objects (NEOs) are a transient population of small bodies with orbits near or in the terrestrial planet region. They represent a mid-stage in the dynamical cycle of asteroids and comets, which starts with their removal from the respective source regions -- the main belt and trans-Neptunian scattered disk -- and ends as bodies impact planets, disintegrate near the Sun, or are ejected from the Solar System. Here we develop a new orbital model of NEOs by numerically integrating asteroid orbits from main belt sources and calibrating the results on observations of the Catalina Sky Survey. The results imply a size-dependent sampling of the main belt with the $\nu_6$ and 3:1 resonances producing $\simeq 30$\% of NEOs with absolute magnitudes $H = 15$ and $\simeq 80$\% of NEOs with $H = 25$. Hence, the large and small NEOs have different orbital distributions. The inferred flux of $H<18$ bodies into the 3:1 resonance can be sustained only if the main-belt asteroids near the resonance drift toward the resonance at the maximal Yarkovsky rate ($\simeq 2 \times 10^{-4}$ au Myr$^{-1}$ for diameter $D=1$ km and semimajor axis $a=2.5$~au). This implies obliquities $\theta \simeq 0^\circ$ for $a<2.5$~au and $\theta \simeq 180^\circ$ for $a>2.5$~au, both in the immediate neighborhood of the resonance (the same applies to other resonances as well). We confirm the size-dependent disruption of asteroids near the Sun found in previous studies. An interested researcher can use the publicly available NEOMOD Simulator to generate user-defined samples of NEOs from our model., Comment: AJ

Published

2023

9. Momentum Transfer from the DART Mission Kinetic Impact on Asteroid Dimorphos

Author

Cheng, Andrew F., Agrusa, Harrison F., Barbee, Brent W., Meyer, Alex J., Farnham, Tony L., Raducan, Sabina D., Richardson, Derek C., Dotto, Elisabetta, Zinzi, Angelo, Della Corte, Vincenzo, Statler, Thomas S., Chesley, Steven, Naidu, Shantanu P., Hirabayashi, Masatoshi, Li, Jian-Yang, Eggl, Siegfried, Barnouin, Olivier S., Chabot, Nancy L., Chocron, Sidney, Collins, Gareth S., Daly, R. Terik, Davison, Thomas M., DeCoster, Mallory E., Ernst, Carolyn M., Ferrari, Fabio, Graninger, Dawn M., Jacobson, Seth A., Jutzi, Martin, Kumamoto, Kathryn M., Luther, Robert, Lyzhoft, Joshua R., Michel, Patrick, Murdoch, Naomi, Nakano, Ryota, Palmer, Eric, Rivkin, Andrew S., Scheeres, Daniel J., Stickle, Angela M., Sunshine, Jessica M., Trigo-Rodriguez, Josep M., Vincent, Jean-Baptiste, Walker, James D., Wünnemann, Kai, Zhang, Yun, Amoroso, Marilena, Bertini, Ivano, Brucato, John R., Capannolo, Andrea, Cremonese, Gabriele, Dall'Ora, Massimo, Deshapriya, Prasanna J. D., Gai, Igor, Hasselmann, Pedro H., Ieva, Simone, Impresario, Gabriele, Ivanovski, Stavro L., Lavagna, Michèle, Lucchetti, Alice, Epifani, Elena M., Modenini, Dario, Pajola, Maurizio, Palumbo, Pasquale, Perna, Davide, Pirrotta, Simone, Poggiali, Giovanni, Rossi, Alessandro, Tortora, Paolo, Zannoni, Marco, and Zanotti, Giovanni

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The NASA Double Asteroid Redirection Test (DART) mission performed a kinetic impact on asteroid Dimorphos, the satellite of the binary asteroid (65803) Didymos, at 23:14 UTC on September 26, 2022 as a planetary defense test. DART was the first hypervelocity impact experiment on an asteroid at size and velocity scales relevant to planetary defense, intended to validate kinetic impact as a means of asteroid deflection. Here we report the first determination of the momentum transferred to an asteroid by kinetic impact. Based on the change in the binary orbit period, we find an instantaneous reduction in Dimorphos's along-track orbital velocity component of 2.70 +/- 0.10 mm/s, indicating enhanced momentum transfer due to recoil from ejecta streams produced by the impact. For a Dimorphos bulk density range of 1,500 to 3,300 kg/m$^3$, we find that the expected value of the momentum enhancement factor, $\beta$, ranges between 2.2 and 4.9, depending on the mass of Dimorphos. If Dimorphos and Didymos are assumed to have equal densities of 2,400 kg/m$^3$, $\beta$= 3.61 +0.19/-0.25 (1 $\sigma$). These $\beta$ values indicate that significantly more momentum was transferred to Dimorphos from the escaping impact ejecta than was incident with DART. Therefore, the DART kinetic impact was highly effective in deflecting the asteroid Dimorphos., Comment: accepted by Nature

Published

2023

10. Successful Kinetic Impact into an Asteroid for Planetary Defense

Author

Daly, R. Terik, Ernst, Carolyn M., Barnouin, Olivier S., Chabot, Nancy L., Rivkin, Andrew S., Cheng, Andrew F., Adams, Elena Y., Agrusa, Harrison F., Abel, Elisabeth D., Alford, Amy L., Asphaug, Erik I., Atchison, Justin A., Badger, Andrew R., Baki, Paul, Ballouz, Ronald-L., Bekker, Dmitriy L., Bellerose, Julie, Bhaskaran, Shyam, Buratti, Bonnie J., Cambioni, Saverio, Chen, Michelle H., Chesley, Steven R., Chiu, George, Collins, Gareth S., Cox, Matthew W., DeCoster, Mallory E., Ericksen, Peter S., Espiritu, Raymond C., Faber, Alan S., Farnham, Tony L., Ferrari, Fabio, Fletcher, Zachary J., Gaskell, Robert W., Graninger, Dawn M., Haque, Musad A., Harrington-Duff, Patricia A., Hefter, Sarah, Herreros, Isabel, Hirabayashi, Masatoshi, Huang, Philip M., Hsieh, Syau-Yun W., Jacobson, Seth A., Jenkins, Stephen N., Jensenius, Mark A., John, Jeremy W., Jutzi, Martin, Kohout, Tomas, Krueger, Timothy O., Laipert, Frank E., Lopez, Norberto R., Luther, Robert, Lucchetti, Alice, Mages, Declan M., Marchi, Simone, Martin, Anna C., McQuaide, Maria E., Michel, Patrick, Moskovitz, Nicholas A., Murphy, Ian W., Murdoch, Naomi, Naidu, Shantanu P., Nair, Hari, Nolan, Michael C., Ormö, Jens, Pajola, Maurizio, Palmer, Eric E., Peachey, James M., Pravec, Petr, Raducan, Sabina D., Ramesh, K. T., Ramirez, Joshua R., Reynolds, Edward L., Richman, Joshua E., Robin, Colas Q., Rodriguez, Luis M., Roufberg, Lew M., Rush, Brian P., Sawyer, Carolyn A., Scheeres, Daniel J., Scheirich, Petr, Schwartz, Stephen R., Shannon, Matthew P., Shapiro, Brett N., Shearer, Caitlin E., Smith, Evan J., Steele, R. Joshua, Steckloff, Jordan K, Stickle, Angela M., Sunshine, Jessica M., Superfin, Emil A., Tarzi, Zahi B., Thomas, Cristina A., Thomas, Justin R., Trigo-Rodríguez, Josep M., Tropf, B. Teresa, Vaughan, Andrew T., Velez, Dianna, Waller, C. Dany, Wilson, Daniel S., Wortman, Kristin A., and Zhang, Yun

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

While no known asteroid poses a threat to Earth for at least the next century, the catalog of near-Earth asteroids is incomplete for objects whose impacts would produce regional devastation. Several approaches have been proposed to potentially prevent an asteroid impact with Earth by deflecting or disrupting an asteroid. A test of kinetic impact technology was identified as the highest priority space mission related to asteroid mitigation. NASA's Double Asteroid Redirection Test (DART) mission is the first full-scale test of kinetic impact technology. The mission's target asteroid was Dimorphos, the secondary member of the S-type binary near-Earth asteroid (65803) Didymos. This binary asteroid system was chosen to enable ground-based telescopes to quantify the asteroid deflection caused by DART's impact. While past missions have utilized impactors to investigate the properties of small bodies those earlier missions were not intended to deflect their targets and did not achieve measurable deflections. Here we report the DART spacecraft's autonomous kinetic impact into Dimorphos and reconstruct the impact event, including the timeline leading to impact, the location and nature of the DART impact site, and the size and shape of Dimorphos. The successful impact of the DART spacecraft with Dimorphos and the resulting change in Dimorphos's orbit demonstrates that kinetic impactor technology is a viable technique to potentially defend Earth if necessary., Comment: Accepted by Nature

Published

2023

11. Orbital Period Change of Dimorphos Due to the DART Kinetic Impact

Author

Thomas, Cristina A., Naidu, Shantanu P., Scheirich, Peter, Moskovitz, Nicholas A., Pravec, Petr, Chesley, Steven R., Rivkin, Andrew S., Osip, David J., Lister, Tim A., Benner, Lance A. M., Brozović, Marina, Contreras, Carlos, Morrell, Nidia, Rożek, Agata, Kušnirák, Peter, Hornoch, Kamil, Mages, Declan, Taylor, Patrick A., Seymour, Andrew D., Snodgrass, Colin, Jørgensen, Uffe G., Dominik, Martin, Skiff, Brian, Polakis, Tom, Knight, Matthew M., Farnham, Tony L., Giorgini, Jon D., Rush, Brian, Bellerose, Julie, Salas, Pedro, Armentrout, William P., Watts, Galen, Busch, Michael W., Chatelain, Joseph, Gomez, Edward, Greenstreet, Sarah, Phillips, Liz, Bonavita, Mariangela, Burgdorf, Martin J., Khalouei, Elahe, Longa-Peña, Penélope, Rabus, Markus, Sajadian, Sedighe, Chabot, Nancy L., Cheng, Andrew F., Ryan, William H., Ryan, Eileen V., Holt, Carrie E., and Agrusa, Harrison F.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The Double Asteroid Redirection Test (DART) spacecraft successfully performed the first test of a kinetic impactor for asteroid deflection by impacting Dimorphos, the secondary of near-Earth binary asteroid (65803) Didymos, and changing the orbital period of Dimorphos. A change in orbital period of approximately 7 minutes was expected if the incident momentum from the DART spacecraft was directly transferred to the asteroid target in a perfectly inelastic collision, but studies of the probable impact conditions and asteroid properties indicated that a considerable momentum enhancement ($\beta$) was possible. In the years prior to impact, we used lightcurve observations to accurately determine the pre-impact orbit parameters of Dimorphos with respect to Didymos. Here we report the change in the orbital period of Dimorphos as a result of the DART kinetic impact to be -33.0 +/- 1.0 (3$\sigma$) minutes. Using new Earth-based lightcurve and radar observations, two independent approaches determined identical values for the change in the orbital period. This large orbit period change suggests that ejecta contributed a significant amount of momentum to the asteroid beyond what the DART spacecraft carried., Comment: Accepted by Nature

Published

2023

12. Anticipating the DART impact: Orbit estimation of Dimorphos using a simplified model

Author

Naidu, Shantanu P., Chesley, Steven R., Farnocchia, Davide, Moskovitz, Nick, Pravec, Petr, Scheirich, Petr, Thomas, Cristina, and Rivkin, Andrew S.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We used the times of occultations and eclipses between the components of the 65803 Didymos binary system observed in its lightcurves from 2003-2021 to estimate the orbital parameters of Dimorphos relative to Didymos. We employed a weighted least-squares approach and a modified Keplerian orbit model in order to accommodate the effects from non-gravitational forces such as Binary YORP that could cause a linear change in mean motion over time. We estimate that the period of the mutual orbit at the epoch 2022 September 26.0 TDB, the day of the DART impact, is $11.9214869 \pm 0.000028$~h ($1\sigma$) and that the mean motion of the orbit is changing at a rate of $(5.0\pm 1.0)\times 10^{-18}$~rad s$^{-2}$ $(1\sigma$). The formal $3\sigma$ uncertainty in orbital phase of Dimorphos during the planned Double Asteroid Redirection Test (DART) mission is $5.4^\circ$. Observations from July to September 2022, a few months to days prior to the DART impact, should provide modest improvements to the orbital phase uncertainty and reduce it to about $4.2^\circ$. These results, generated using a relatively simple model, are consistent with those generated using the more sophisticated model of \citet{scheirich22}, which demonstrates the reliability of our method and adds confidence to these mission-critical results., Comment: Accepted to PSJ

Published

2022

13. Bistatic Radar Observations of Near-Earth Asteroid (163899) 2003 SD220 from the Southern Hemisphere

Author

Horiuchi, Shinji, Molyneux, Blake, Stevens, Jamie B., Baines, Graham, Benson, Craig, Abu-Shaban, Zohair, Giorgini, Jon D., Benner, Lance A. M., Naidu, Shantanu P., Phillips, Chris J., Edwards, Philip G., Kruzins, Ed, Stacy, Nick J. S., Slade, Martin A., Reynolds, John E., and Lazio, Joseph

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We report results of Canberra-ATCA Doppler-only continuous wave (CW) radar observations of near-Earth asteroid (163899) 2003 SD220 at a receiving frequency of 7159 MHz (4.19 cm) on 2018 December 20, 21, and 22 during its close approach within 0.019 au (7.4 lunar distances). Echo power spectra provide evidence that the shape is significantly elongated, asymmetric, and has at least one relatively large concavity. An average spectrum per track yields an OC (opposite sense of circular polarisation) radar cross section of 0.39, 0.27, and 0.25 km$^{2}$, respectively, with an uncertainty of 35 \%. Variations by roughly a factor of two in the limb-to-limb bandwidth over the three days indicate rotation of an elongated object. We obtain a circular polarization ratio of 0.21 $\pm$ 0.07 that is consistent with, but somewhat lower than, the average among other S-class near-Earth asteroids observed by radar., Comment: 15 pages, 4 figures, accepted for publication in Icarus

Published

2020

14. Establishing Earth's Minimoon Population through Characterization of Asteroid 2020 CD$_3$

Author

Fedorets, Grigori, Micheli, Marco, Jedicke, Robert, Naidu, Shantanu P., Farnocchia, Davide, Granvik, Mikael, Moskovitz, Nicholas, Schwamb, Megan E., Weryk, Robert, Wierzchoś, Kacper, Christensen, Eric, Pruyne, Theodore, Bottke, William F., Ye, Quanzhi, Wainscoat, Richard, Devogèle, Maxime, Buchanan, Laura E., Djupvik, Anlaug Amanda, Faes, Daniel M., Föhring, Dora, Roediger, Joel, Seccull, Tom, and Smith, Adam B.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We report on our detailed characterization of Earth's second known temporary natural satellite, or minimoon, asteroid 2020 CD3. An artificial origin can be ruled out based on its area-to-mass ratio and broadband photometry, which suggest that it is a silicate asteroid belonging to the S or V complex in asteroid taxonomy. The discovery of 2020 CD3 allows for the first time a comparison between known minimoons and theoretical models of their expected physical and dynamical properties. The estimated diameter of 1.2+0.4-0.2 m and geocentric capture approximately a decade after the first known minimoon, 2006 RH120, are in agreement with theoretical predictions. The capture duration of 2020 CD3 of at least 2.7 yr is unexpectedly long compared to the simulation average, but it is in agreement with simulated minimoons that have close lunar encounters, providing additional support for the orbital models. 2020 CD3's atypical rotation period, significantly longer than theoretical predictions, suggests that our understanding of meter-scale asteroids needs revision. More discoveries and a detailed characterization of the population can be expected with the forthcoming Vera C. Rubin Observatory Legacy Survey of Space and Time., Comment: 22 pages, 6 Figures, 5 Tables, to appear in the Astronomical Journal

Published

2020

15. Planetary Bistatic Radar

Author

Brozovic, M., Butler, B. J., Margot, Jean-Luc, Naidu, Shantanu P., and Lazio, T. Joseph W.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Planetary radar observations offer the potential for probing the properties of characteristics of solid bodies throughout the inner solar system and at least as far as the orbit of Saturn. In addition to the direct scientific value, precise orbital determinations can be obtained from planetary radar observations, which are in turn valuable for mission planning or spacecraft navigation and planetary defense. The next-generation Very Large Array would not have to be equipped with a transmitter to be an important asset in the world's planetary radar infrastructure. Bistatic radar, in which one antenna transmits (e.g., Arecibo or Goldstone) and another receives, are used commonly today, with the Green Bank Telescope (GBT) serving as a receiver. The improved sensitivity of the ngVLA relative to the GBT would improve the signal-to-noise ratios on many targets and increase the accessible volume specifically for asteroids. Goldstone-ngVLA bistatic observations would have the potential of rivaling the sensitivity of Arecibo, but with much wider sky access., Comment: 11 pages, 2 figures, To be published in the ASP Monograph Series, "Science with a Next-Generation VLA", ed. E. J. Murphy (ASP, San Francisco, CA)

Published

2018

16. Search for OH 18-cm radio emission from 1I/2017 U1 with the Green Bank telescope

Author

Park, Ryan S., Pisano, D. J., Lazio, T. Joseph W., Chodas, Paul W., and Naidu, Shantanu P.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

This paper reports the first OH 18-cm line observation of the first detected interstellar object 1I/2017 U1 (`Oumuamua) using the Green Bank Telescope. We have observed the OH lines at 1665.402 MHz, 1667.359, and 1720.53 MHz frequencies with a spectral resolution of 357 Hz (approximately 0.06 km-s^{-1}). At the time of the observation, `Oumuamua was at topocentric distance and velocity of 1.07 au and 63.4 km-s^{-1}, respectively, or at heliocentric distance and velocity of 1.8 au and 39 km-s^{-1}, respectively. Based on a detailed data reduction and an analogy-based inversion, our final results confirm the asteroidal origin of `Oumuamua (as discussed in Meech et al., 2017) with an upper bound of OH production of Q[OH] < 0.17 x 10^{28} s^{-1}., Comment: accepted for publication in Astronomical Journal, 7 pages, 1 figure, 1 table

Published

2018

17. Constraints on the perturbed mutual motion in Didymos due to impact-induced deformation of its primary after the DART impact

Author

Hirabayashi, Masatoshi, Schwartz, Stephen R., Yu, Yang, Davis, Alex B., Chesley, Steven R., Fahnestock, Eugene G., Michel, Patrick, Richardson, Derek C., Naidu, Shantanu P., Scheeres, Daniel J., Cheng, Andrew F., Rivkin, Andrew S., and Benner, Lance A. M.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Binary near-Earth asteroid (65803) Didymos is the target of the proposed NASA Double Asteroid Redirection Test (DART), part of the Asteroid Impact & Deflection Assessment (AIDA) mission concept. In this mission, the DART spacecraft is planned to impact the secondary body of Didymos, perturbing mutual dynamics of the system. The primary body is currently rotating at a spin period close to the spin barrier of asteroids, and materials ejected from the secondary due to the DART impact are likely to reach the primary. These conditions may cause the primary to reshape, due to landslides, or internal deformation, changing the permanent gravity field. Here, we propose that if shape deformation of the primary occurs, the mutual orbit of the system would be perturbed due to a change in the gravity field. We use a numerical simulation technique based on the full two-body problem to investigate the shape effect on the mutual dynamics in Didymos after the DART impact. The results show that under constant volume, shape deformation induces strong perturbation in the mutual motion. We find that the deformation process always causes the orbital period of the system to become shorter. If surface layers with a thickness greater than ~0.4 m on the poles of the primary move down to the equatorial region due to the DART impact, a change in the orbital period of the system and in the spin period of the primary will be detected by ground-based measurement., Comment: 8 pages, 7 figures, 2 tables, accepted for publication in MNRAS

Published

2017

18. Creep stability of the proposed AIDA mission target 65803 Didymos: I. Discrete cohesionless granular physics model

Author

Zhang, Yun, Richardson, Derek C., Barnouin, Olivier S., Maurel, Clara, Michel, Patrick, Schwartz, Stephen R., Ballouz, Ronald-Louis, Benner, Lance A. M., Naidu, Shantanu P., and Li, Junfeng

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

As the target of the proposed Asteroid Impact & Deflection Assessment (AIDA) mission, the near-Earth binary asteroid 65803 Didymos represents a special class of binary asteroids, those whose primaries are at risk of rotational disruption. To gain a better understanding of these binary systems and to support the AIDA mission, this paper investigates the creep stability of the Didymos primary by representing it as a cohesionless self-gravitating granular aggregate subject to rotational acceleration. To achieve this goal, a soft-sphere discrete element model (SSDEM) capable of simulating granular systems in quasi-static states is implemented and a quasi-static spin-up procedure is carried out. We devise three critical spin limits for the simulated aggregates to indicate their critical states triggered by reshaping and surface shedding, internal structural deformation, and shear failure, respectively. The failure condition and mode, and shear strength of an aggregate can all be inferred from the three critical spin limits. The effects of arrangement and size distribution of constituent particles, bulk density, spin-up path, and interparticle friction are numerically explored. The results show that the shear strength of a spinning self-gravitating aggregate depends strongly on both its internal configuration and material parameters, while its failure mode and mechanism are mainly affected by its internal configuration. Additionally, this study provides some constraints on the possible physical properties of the Didymos primary based on observational data and proposes a plausible formation mechanism for this binary system. With a bulk density consistent with observational uncertainty and close to the maximum density allowed for the asteroid, the Didymos primary in certain configurations can remain geo-statically stable without including cohesion., Comment: 66 pages, 24 figures, submitted to Icarus on 25/Aug/2016

Published

2017

19. Planetary Bistatic Radar

Author

Brozovic, M, Butler, BJ, Margot, Jean-Luc, Naidu, Shantanu P, and Lazio, T Joseph W

Subjects

astro-ph.EP

Abstract

Planetary radar observations offer the potential for probing the propertiesof characteristics of solid bodies throughout the inner solar system and atleast as far as the orbit of Saturn. In addition to the direct scientificvalue, precise orbital determinations can be obtained from planetary radarobservations, which are in turn valuable for mission planning or spacecraftnavigation and planetary defense. The next-generation Very Large Array wouldnot have to be equipped with a transmitter to be an important asset in theworld's planetary radar infrastructure. Bistatic radar, in which one antennatransmits (e.g., Arecibo or Goldstone) and another receives, are used commonlytoday, with the Green Bank Telescope (GBT) serving as a receiver. The improvedsensitivity of the ngVLA relative to the GBT would improve the signal-to-noiseratios on many targets and increase the accessible volume specifically forasteroids. Goldstone-ngVLA bistatic observations would have the potential ofrivaling the sensitivity of Arecibo, but with much wider sky access.

Published

2018

20. Dimorphos’s Orbit Period Change and Attitude Perturbation due to Its Reshaping after the DART Impact

Author

Nakano, Ryota, primary, Hirabayashi, Masatoshi, additional, Raducan, Sabina D., additional, Pravec, Petr, additional, Naidu, Shantanu P., additional, Agrusa, Harrison F., additional, Chesley, Steven, additional, Ferrari, Fabio, additional, Jutzi, Martin, additional, Merrill, Colby C., additional, Meyer, Alex J., additional, Michel, Patrick, additional, Richardson, Derek C., additional, Sánchez, Paul, additional, Scheirich, Peter, additional, Schwartz, Stephen R., additional, Zhang, Yun, additional, Bagatin, Adriano Campo, additional, Liu, Po-Yen, additional, and Cheng, Andrew F., additional

Published

2024

21. Radar and Optical Observations and Physical Modeling of Binary Near-Earth Asteroid 2018 EB

Author

Brozović, Marina, primary, Benner, Lance A. M., additional, Naidu, Shantanu P., additional, Moskovitz, Nicholas, additional, Giorgini, Jon D., additional, Virkki, Anne K., additional, Marshall, Sean E., additional, Dover, Lord R., additional, Rożek, Agata, additional, Lowry, Stephen C., additional, Warner, Brian D., additional, Taylor, Patrick A., additional, Rivera-Valentin, Edgard G., additional, Lister, Timothy A., additional, Chatelain, Joseph P., additional, Busch, Michael W., additional, Magri, Christopher, additional, Jao, Joseph S., additional, Snedeker, Lawrence G., additional, and Lawrence, Kenneth J., additional

Published

2024

22. Asteroid 1566 Icarus's size, shape, orbit, and Yarkovsky drift from radar observations

Author

Greenberg, Adam H., Margot, Jean-Luc, Verma, Ashok K., Taylor, Patrick A., Naidu, Shantanu P., Brozovic, Marina., and Benner, Lance A. M.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Near-Earth asteroid (NEA) 1566 Icarus ($a=1.08$ au, $e=0.83$, $i=22.8^{\circ}$) made a close approach to Earth in June 2015 at 22 lunar distances (LD). Its detection during the 1968 approach (16 LD) was the first in the history of asteroid radar astronomy. A subsequent approach in 1996 (40 LD) did not yield radar images. We describe analyses of our 2015 radar observations of Icarus obtained at the Arecibo Observatory and the DSS-14 antenna at Goldstone. These data show that the asteroid is a moderately flattened spheroid with an equivalent diameter of 1.44 km with 18% uncertainties, resolving long-standing questions about the asteroid size. We also solve for Icarus' spin axis orientation ($\lambda=270^{\circ}\pm10^{\circ}, \beta=-81^{\circ}\pm10^{\circ}$), which is not consistent with the estimates based on the 1968 lightcurve observations. Icarus has a strongly specular scattering behavior, among the highest ever measured in asteroid radar observations, and a radar albedo of $\sim$2\%, among the lowest ever measured in asteroid radar observations. The low cross-section suggests a high-porosity surface, presumably related to Icarus' cratering, spin, and thermal histories. Finally, we present the first use of our orbit determination software for the generation of observational ephemerides, and we demonstrate its ability to determine subtle perturbations on NEA orbits by measuring Icarus' orbit-averaged drift in semi-major axis ($(-4.62\pm0.48) \times 10^{-4}$ au/My, or $\sim$60 m per revolution). Our Yarkovsky rate measurement resolves a discrepancy between two published rates that did not include the 2015 radar astrometry., Comment: 19 pages, 6 figures. The Astronomical Journal, in press

Published

2016

23. Capabilities of Earth-based radar facilities for near-Earth asteroid observations

Author

Naidu, Shantanu. P., Benner, Lance. A. M., Margot, Jean-Luc, Busch, Michael. W., and Taylor, Patrick. A.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

We evaluated the planetary radar capabilities at Arecibo, the Goldstone 70-m DSS-14 and 34-m DSS-13 antennas, the 70-m DSS-43 antenna at Canberra, the Green Bank Telescope, and the Parkes Radio Telescope in terms of their relative sensitivities and the number of known near-Earth asteroids (NEAs) detectable per year in monostatic and bistatic configurations. In the 2015 calendar year, monostatic observations with Arecibo and DSS-14 were capable of detecting 253 and 131 NEAs respectively, with signal-to-noise ratios (SNRs) greater than 30/track. Combined, the two observatories were capable of detecting 276 NEAs. Of these, Arecibo detected 77 and Goldstone detected 32, or 30% and 24% the numbers that were possible. The two observatories detected an additional 18 and 7 NEAs respectively, with SNRs of less than 30/track. This indicates that a substantial number of potential targets are not being observed. The bistatic configuration with DSS-14 transmitting and the Green Bank Telescope receiving was capable of detecting about 195 NEAs, or ~50% more than with monostatic observations at DSS-14. Most of the detectable asteroids were targets of opportunity that were discovered less than 15 days before the end of their observing windows. About 50% of the detectable asteroids have absolute magnitudes > 25, which corresponds diameters < ~30 m., Comment: 12 pages, 7 figures, Accepted to AJ

Published

2016

24. Ejecta Cloud from a Kinetic Impact on the Secondary of a Binary Asteroid: I. Mechanical Environment and Dynamic Model

Author

Yu, Yang, Michel, Patrick, Schwartz, Stephen R., Naidu, Shantanu P., and Benner, Lance A. M.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

An understanding of the post-impact dynamics of ejecta clouds are crucial to the planning of a kinetic impact mission to an asteroid, and also has great implications for the history of planetary formation. The purpose of this article to track the evolution of ejecta produced by AIDA mission, which targets for kinetic impact the secondary of near-Earth binary asteroid 65803 Didymos on 2022, and to feedback essential informations to AIDA's ongoing phase-A study. We present a detailed dynamic model for the simulation of an ejecta cloud from a binary asteroid that synthesizes all relevant forces based on a previous analysis of the mechanical environment. We apply our method to gain insight into the expected response of Didymos to the AIDA impact, including the subsequent evolution of debris and dust. The crater scaling relations from laboratory experiments are employed to approximate the distributions of ejecta mass and launching speed. The size composition of fragments is modeled with a power law fitted from observations of real asteroid surface. A full-scale demonstration is simulated using parameters specified by the mission. We report the results of the simulation, which include the computed spread of the ejecta cloud and the recorded history of ejecta accretion and escape. The violent period of the ejecta evolution is found to be short, and is followed by a stage where the remaining ejecta is gradually cleared. Solar radiation pressure proves to be efficient in cleaning dust-size ejecta, and the simulation results after two weeks shows that large debris on polar orbits (perpendicular to the binary orbital plane) has a survival advantage over smaller ejecta and ejecta that keep to low latitudes., Comment: 50 pages, 9 figures

Published

2016

25. Bistatic radar observations of near-earth asteroid (163899) 2003 SD220 from the southern hemisphere

Author

Horiuchi, Shinji, Molyneux, Blake, Stevens, Jamie B., Baines, Graham, Benson, Craig, Abu-Shaban, Zohair, Giorgini, Jon D., Benner, Lance A.M., Naidu, Shantanu P., Phillips, Chris J., Edwards, Philip G., Kruzins, Ed, Stacy, Nick J.S., Slade, Martin A., Reynolds, John E., and Lazio, Joseph

Published

2021

26. Photometry of the Didymos System across the DART Impact Apparition

Author

Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Moskovitz, Nicholas A., Thomas, Cristina, Pravec, Petr, Lister, Tim, Polakis, Tom, Osip, David, Kareta, Teddy, Rożek, Agata, Chesley, Steven, Naidu, Shantanu P., Scheirich, Peter, Ryan, William, Ryan, Eileen, Skiff, Brian, Snodgrass, Colin, Knight, Matthew M., Rivkin, Andy, Chabot, Nancy, Ayvazian, Vova, Belskaya, Irina, Benkhaldoun, Zouhair, Berteşteanu, Daniel N., Bonavita, Mariangela, Bressi, Terrence H., Brucker, Melissa J., Burgdorf, Martin J., Burkhonov, Otabek, Burt, Brian, Contreras, Carlos, Chatelain, Joseph, Choi, Young-Jun, Daily, Matthew, de León, Julia, Ergashev, Kamoliddin, Farnham, Tony, Fatka, Petr, Ferrais, Marin, Geier, Stefan, Gomez, Edward, Greenstreet, Sarah, Gröller, Hannes, Hergenrother, Carl, Holt, Carrie, Hornoch, Kamil, Husárik, Marek, Inasaridze, Raguli, Jehin, Emmanuel, Khalouei, Elahe, Kikwaya Eluo, Jean-Baptiste, Kim, Myung-Jin, Krugly, Yurij, Kučáková, Hana, Kušnirák, Peter, Larsen, Jeffrey A., Lee, Hee-Jae, Lejoly, Cassandra, Licandro, Javier, Longa-Peña, Penélope, Mastaler, Ronald A., McCully, Curtis, Moon, Hong-Kyu, Morrell, Nidia I., Nath, Arushi, Oszkiewicz, Dagmara, Parrott, Daniel, Phillips, Liz, Popescu, Marcel, Pray, Donald, Prodan, George Pantelimon, Rabus, Markus, Read, Michael T., Reva, Inna, Roark, Vernon, Santana-Ros, Toni, Scotti, James V., Tatara, Taiyo, Thirouin, Audrey, Tholen, David J., Troianskyi, Volodymyr, Tubbiolo, Andrew F., Villa, Katelyn, Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Moskovitz, Nicholas A., Thomas, Cristina, Pravec, Petr, Lister, Tim, Polakis, Tom, Osip, David, Kareta, Teddy, Rożek, Agata, Chesley, Steven, Naidu, Shantanu P., Scheirich, Peter, Ryan, William, Ryan, Eileen, Skiff, Brian, Snodgrass, Colin, Knight, Matthew M., Rivkin, Andy, Chabot, Nancy, Ayvazian, Vova, Belskaya, Irina, Benkhaldoun, Zouhair, Berteşteanu, Daniel N., Bonavita, Mariangela, Bressi, Terrence H., Brucker, Melissa J., Burgdorf, Martin J., Burkhonov, Otabek, Burt, Brian, Contreras, Carlos, Chatelain, Joseph, Choi, Young-Jun, Daily, Matthew, de León, Julia, Ergashev, Kamoliddin, Farnham, Tony, Fatka, Petr, Ferrais, Marin, Geier, Stefan, Gomez, Edward, Greenstreet, Sarah, Gröller, Hannes, Hergenrother, Carl, Holt, Carrie, Hornoch, Kamil, Husárik, Marek, Inasaridze, Raguli, Jehin, Emmanuel, Khalouei, Elahe, Kikwaya Eluo, Jean-Baptiste, Kim, Myung-Jin, Krugly, Yurij, Kučáková, Hana, Kušnirák, Peter, Larsen, Jeffrey A., Lee, Hee-Jae, Lejoly, Cassandra, Licandro, Javier, Longa-Peña, Penélope, Mastaler, Ronald A., McCully, Curtis, Moon, Hong-Kyu, Morrell, Nidia I., Nath, Arushi, Oszkiewicz, Dagmara, Parrott, Daniel, Phillips, Liz, Popescu, Marcel, Pray, Donald, Prodan, George Pantelimon, Rabus, Markus, Read, Michael T., Reva, Inna, Roark, Vernon, Santana-Ros, Toni, Scotti, James V., Tatara, Taiyo, Thirouin, Audrey, Tholen, David J., Troianskyi, Volodymyr, Tubbiolo, Andrew F., and Villa, Katelyn

Abstract

On 2022 September 26, the Double Asteroid Redirection Test (DART) spacecraft impacted Dimorphos, the satellite of binary near-Earth asteroid (65803) Didymos. This demonstrated the efficacy of a kinetic impactor for planetary defense by changing the orbital period of Dimorphos by 33 minutes. Measuring the period change relied heavily on a coordinated campaign of lightcurve photometry designed to detect mutual events (occultations and eclipses) as a direct probe of the satellite's orbital period. A total of 28 telescopes contributed 224 individual lightcurves during the impact apparition from 2022 July to 2023 February. We focus here on decomposable lightcurves, i.e., those from which mutual events could be extracted. We describe our process of lightcurve decomposition and use that to release the full data set for future analysis. We leverage these data to place constraints on the postimpact evolution of ejecta. The measured depths of mutual events relative to models showed that the ejecta became optically thin within the first ∼1 day after impact and then faded with a decay time of about 25 days. The bulk magnitude of the system showed that ejecta no longer contributed measurable brightness enhancement after about 20 days postimpact. This bulk photometric behavior was not well represented by an HG photometric model. An HG1G2 model did fit the data well across a wide range of phase angles. Lastly, we note the presence of an ejecta tail through at least 2023 March. Its persistence implied ongoing escape of ejecta from the system many months after DART impact.

Published

2024

27. 2023 DZ2 Planetary Defense Campaign

Author

Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Reddy, Vishnu, Kelley, Michael S., Benner, Lance, Dotson, Jessie, Erasmus, Nicolas, Farnocchia, Davide, Linder, Tyler, Masiero, Joseph R., Thomas, Cristina, Bauer, James M., Alarcon, Miguel R., Bacci, P., Bamberger, Daniel, Battle, Adam, Benkhaldoun, Zouhair, Betti, Guido, Birlan, Mirel, Brozovic, Marina, Burt, Brian, Cantillo, David C., Chandra, Sunil, Chomette, Gregoire, Coates, Ashley, DeMeo, Francesca, Devogèle, Maxime, Fatka, Petr, Ferrais, Marin, Fini, Paolo, van Gend, Carel, Giorgini, Jon D., Glamazda, Dmitry, Holmes, Robert, Hora, Joseph L., Horiuchi, Shinji, Hornoch, Kamil, Iozzi, Marco, Jacques, Cristóvão, Jehin, Emmanuel, Jiang, Hai, Kaiser, Galina, Kušnirák, Peter, Kuznetsov, Eduard, de León, Julia, Liakos, Alexios, Licandro, Javier, Lister, Tim, Liu, Jing, Lopez-Oquendo, Andy, Maestripieri, M., Mathias, Donovan, Micheli, Marco, Naidu, Shantanu P., Nastasi, Alessandro, Nedelcu, Alin, Petrescu, Elisabeta, Popescu, Marcel, Potter, Stephen B., Pravec, Petr, Sanchez, Juan, Santana-Ros, Toni, Serra-Ricart, M., Sioulas, Nick, Sonka, Adrian B., Squilloni, Alessio, Tombelli, Maura, Trelia, Madalina M., Trilling, David, Warner, Elizabeth M., Wells, Guy, Wheeler, Lorien, Wiles, Mike, Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Reddy, Vishnu, Kelley, Michael S., Benner, Lance, Dotson, Jessie, Erasmus, Nicolas, Farnocchia, Davide, Linder, Tyler, Masiero, Joseph R., Thomas, Cristina, Bauer, James M., Alarcon, Miguel R., Bacci, P., Bamberger, Daniel, Battle, Adam, Benkhaldoun, Zouhair, Betti, Guido, Birlan, Mirel, Brozovic, Marina, Burt, Brian, Cantillo, David C., Chandra, Sunil, Chomette, Gregoire, Coates, Ashley, DeMeo, Francesca, Devogèle, Maxime, Fatka, Petr, Ferrais, Marin, Fini, Paolo, van Gend, Carel, Giorgini, Jon D., Glamazda, Dmitry, Holmes, Robert, Hora, Joseph L., Horiuchi, Shinji, Hornoch, Kamil, Iozzi, Marco, Jacques, Cristóvão, Jehin, Emmanuel, Jiang, Hai, Kaiser, Galina, Kušnirák, Peter, Kuznetsov, Eduard, de León, Julia, Liakos, Alexios, Licandro, Javier, Lister, Tim, Liu, Jing, Lopez-Oquendo, Andy, Maestripieri, M., Mathias, Donovan, Micheli, Marco, Naidu, Shantanu P., Nastasi, Alessandro, Nedelcu, Alin, Petrescu, Elisabeta, Popescu, Marcel, Potter, Stephen B., Pravec, Petr, Sanchez, Juan, Santana-Ros, Toni, Serra-Ricart, M., Sioulas, Nick, Sonka, Adrian B., Squilloni, Alessio, Tombelli, Maura, Trelia, Madalina M., Trilling, David, Warner, Elizabeth M., Wells, Guy, Wheeler, Lorien, and Wiles, Mike

Abstract

We present the results of a fourth planetary defense exercise, focused this time on the small near-Earth asteroid (NEA) 2023 DZ2 and conducted during its close approach to the Earth in 2023 March. The International Asteroid Warning Network (IAWN), with support from NASA's Planetary Defense Coordination Office (PDCO), has been coordinating planetary defense observational campaigns since 2017 to test the operational readiness of the global planetary defense capabilities. The last campaign focused on the NEA Apophis, and an outcome of that exercise was the need for a short burst campaign to replicate a real-life near-Earth object impact hazard scenario. The goal of the 2023 DZ2 campaign was to characterize the small NEA as a potential impactor and exercise the planetary defense system including observations, hypothetical risk assessment and risk prediction, and hazard communication with a short notice of just 24 hr. The entire campaign lasted about 10 days. The campaign team was divided into several working groups based on the characterization method: photometry, spectroscopy, thermal IR photometry and optical polarimetry, radar, and risk assessment. Science results from the campaign show that 2023 DZ2 has a rotation period of 6.2745 ± 0.0030 minutes; visible wavelength color photometry/spectroscopy/polarimetry and near-IR spectroscopy all point to an E-type taxonomic classification with surface composition analogous to aubrite meteorites; and radar observations show that the object has a diameter of 30 ± 10 m, consistent with the high albedo (0.49) derived from polarimetric and thermal IR observations.

Published

2024

28. Radar Imaging and Characterization of Binary Near-Earth Asteroid (185851) 2000 DP107

Author

Naidu, Shantanu P., Margot, Jean-Luc, Taylor, Patrick A., Nolan, Michael C., Busch, Michael W., Benner, Lance A. M., Brozovic, Marina, Giorgini, Jon D., Jao, Joseph S., and Magri, Chris

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Potentially hazardous asteroid (185851) 2000 DP107 was the first binary near-Earth asteroid to be imaged. Radar observations in 2000 provided images at 75 m resolution that revealed the shape, orbit, and spin-up formation mechanism of the binary. The asteroid made a more favorable flyby of the Earth in 2008, yielding images at 30 m resolution. We used these data to obtain shape models for the two components and to improve the estimates of the mutual orbit, component masses, and spin periods. The primary has a sidereal spin period of 2.7745 +/- 0.0007 h and is roughly spheroidal with an equivalent diameter of 863 m +/- 5 %. It has a mass of 4.656 +/- 0.43 x 10^11 kg and a density of 1381 +/- 244 kg m^{-3}. It exhibits an equatorial ridge similar to the (66391) 1999 KW4 primary, however the equatorial ridge in this case is not as regular and has a ~300 m diameter concavity on one side. The secondary has a sidereal spin period of 1.77 +/- 0.02 days commensurate with the orbital period. The secondary is slightly elongated and has overall dimensions of 377 x 314 x 268 m (6 % uncertainties). Its mass is 0.178 +/- 0.021 x 10^{11} kg and its density is 1047 +/- 230 kg m^{-3}. The mutual orbit has a semi-major axis of 2.659 +/- 0.08 km, an eccentricity of 0.019 +/- 0.01, and a period of 1.7556 +/- 0.0015 days. The normalized total angular momentum of this system exceeds the amount required for the expected spin-up formation mechanism. An increase of angular momentum from non-gravitational forces after binary formation is a possible explanation. The two components have similar radar reflectivity, suggesting a similar composition consistent with formation by spin-up. The secondary appears to exhibit a larger circular polarization ratio than the primary, suggesting a rougher surface or subsurface at radar wavelength scales., Comment: 13 pages, 9 figures, Accepted to The Astronomical Journal

Published

2015

29. Orbital and Physical Characterization of Asteroid Dimorphos Following the DART Impact

Author

Naidu, Shantanu P., primary, Chesley, Steven R., additional, Moskovitz, Nicholas, additional, Thomas, Cristina, additional, Meyer, Alex J., additional, Pravec, Petr, additional, Scheirich, Peter, additional, Farnocchia, Davide, additional, Scheeres, Daniel J., additional, Brozovic, Marina, additional, Benner, Lance A. M., additional, Rivkin, Andrew S., additional, and Chabot, Nancy L., additional

Published

2024

30. Photometry of the Didymos System across the DART Impact Apparition

Author

Moskovitz, Nicholas, primary, Thomas, Cristina, additional, Pravec, Petr, additional, Lister, Tim, additional, Polakis, Tom, additional, Osip, David, additional, Kareta, Theodore, additional, Rożek, Agata, additional, Chesley, Steven R., additional, Naidu, Shantanu P., additional, Scheirich, Peter, additional, Ryan, William, additional, Ryan, Eileen, additional, Skiff, Brian, additional, Snodgrass, Colin, additional, Knight, Matthew M., additional, Rivkin, Andrew S., additional, Chabot, Nancy L., additional, Ayvazian, Vova, additional, Belskaya, Irina, additional, Benkhaldoun, Zouhair, additional, Berteşteanu, Daniel N., additional, Bonavita, Mariangela, additional, Bressi, Terrence H., additional, Brucker, Melissa J., additional, Burgdorf, Martin J., additional, Burkhonov, Otabek, additional, Burt, Brian, additional, Contreras, Carlos, additional, Chatelain, Joseph, additional, Choi, Young-Jun, additional, Daily, Matthew, additional, de León, Julia, additional, Ergashev, Kamoliddin, additional, Farnham, Tony, additional, Fatka, Petr, additional, Ferrais, Marin, additional, Geier, Stefan, additional, Gomez, Edward, additional, Greenstreet, Sarah, additional, Gröller, Hannes, additional, Hergenrother, Carl, additional, Holt, Carrie, additional, Hornoch, Kamil, additional, Husárik, Marek, additional, Inasaridze, Raguli, additional, Jehin, Emmanuel, additional, Khalouei, Elahe, additional, Eluo, Jean-Baptiste Kikwaya, additional, Kim, Myung-Jin, additional, Krugly, Yurij, additional, Kučáková, Hana, additional, Kušnirák, Peter, additional, Larsen, Jeffrey A., additional, Lee, Hee-Jae, additional, Lejoly, Cassandra, additional, Licandro, Javier, additional, Longa-Peña, Penélope, additional, Mastaler, Ronald A., additional, McCully, Curtis, additional, Moon, Hong-Kyu, additional, Morrell, Nidia, additional, Nath, Arushi, additional, Oszkiewicz, Dagmara, additional, Parrott, Daniel, additional, Phillips, Liz, additional, Popescu, Marcel M., additional, Pray, Donald, additional, Prodan, George Pantelimon, additional, Rabus, Markus, additional, Read, Michael T., additional, Reva, Inna, additional, Roark, Vernon, additional, Santana-Ros, Toni, additional, Scotti, James V., additional, Tatara, Taiyo, additional, Thirouin, Audrey, additional, Tholen, David, additional, Troianskyi, Volodymyr, additional, Tubbiolo, Andrew F., additional, and Villa, Katelyn, additional

Published

2024

31. Measurability of the Heliocentric Momentum Enhancement from a Kinetic Impact: The Double Asteroid Redirection Test (DART) Mission

Author

Makadia, Rahil, primary, Chesley, Steven R., additional, Farnocchia, Davide, additional, Naidu, Shantanu P., additional, Souami, Damya, additional, Tanga, Paolo, additional, Tsiganis, Kleomenis, additional, Hirabayashi, Masatoshi, additional, and Eggl, Siegfried, additional

Published

2024

32. Achievement of the Planetary Defense Investigations of the Double Asteroid Redirection Test (DART) Mission

Author

Chabot, Nancy L., primary, Rivkin, Andrew S., additional, Cheng, Andrew F., additional, Barnouin, Olivier S., additional, Fahnestock, Eugene G., additional, Richardson, Derek C., additional, Stickle, Angela M., additional, Thomas, Cristina A., additional, Ernst, Carolyn M., additional, Terik Daly, R., additional, Dotto, Elisabetta, additional, Zinzi, Angelo, additional, Chesley, Steven R., additional, Moskovitz, Nicholas A., additional, Barbee, Brent W., additional, Abell, Paul, additional, Agrusa, Harrison F., additional, Bannister, Michele T., additional, Beccarelli, Joel, additional, Bekker, Dmitriy L., additional, Bruck Syal, Megan, additional, Buratti, Bonnie J., additional, Busch, Michael W., additional, Campo Bagatin, Adriano, additional, Chatelain, Joseph P., additional, Chocron, Sidney, additional, Collins, Gareth S., additional, Conversi, Luca, additional, Davison, Thomas M., additional, DeCoster, Mallory E., additional, Prasanna Deshapriya, J. D., additional, Eggl, Siegfried, additional, Espiritu, Raymond C., additional, Farnham, Tony L., additional, Ferrais, Marin, additional, Ferrari, Fabio, additional, Föhring, Dora, additional, Fuentes-Muñoz, Oscar, additional, Gai, Igor, additional, Giordano, Carmine, additional, Glenar, David A., additional, Gomez, Edward, additional, Graninger, Dawn M., additional, Green, Simon F., additional, Greenstreet, Sarah, additional, Hasselmann, Pedro H., additional, Herreros, Isabel, additional, Hirabayashi, Masatoshi, additional, Husárik, Marek, additional, Ieva, Simone, additional, Ivanovski, Stavro L., additional, Jackson, Samuel L., additional, Jehin, Emmanuel, additional, Jutzi, Martin, additional, Karatekin, Ozgur, additional, Knight, Matthew M., additional, Kolokolova, Ludmilla, additional, Kumamoto, Kathryn M., additional, Küppers, Michael, additional, La Forgia, Fiorangela, additional, Lazzarin, Monica, additional, Li, Jian-Yang, additional, Lister, Tim A., additional, Lolachi, Ramin, additional, Lucas, Michael P., additional, Lucchetti, Alice, additional, Luther, Robert, additional, Makadia, Rahil, additional, Mazzotta Epifani, Elena, additional, McMahon, Jay, additional, Merisio, Gianmario, additional, Merrill, Colby C., additional, Meyer, Alex J., additional, Michel, Patrick, additional, Micheli, Marco, additional, Migliorini, Alessandra, additional, Minker, Kate, additional, Modenini, Dario, additional, Moreno, Fernando, additional, Murdoch, Naomi, additional, Murphy, Brian, additional, Naidu, Shantanu P., additional, Nair, Hari, additional, Nakano, Ryota, additional, Opitom, Cyrielle, additional, Ormö, Jens, additional, Michael Owen, J., additional, Pajola, Maurizio, additional, Palmer, Eric E., additional, Palumbo, Pasquale, additional, Panicucci, Paolo, additional, Parro, Laura M., additional, Pearl, Jason M., additional, Penttilä, Antti, additional, Perna, Davide, additional, Petrescu, Elisabeta, additional, Pravec, Petr, additional, Raducan, Sabina D., additional, Ramesh, K. T., additional, Ridden-Harper, Ryan, additional, Rizos, Juan L., additional, Rossi, Alessandro, additional, Roth, Nathan X., additional, Rożek, Agata, additional, Rozitis, Benjamin, additional, Ryan, Eileen V., additional, Ryan, William H., additional, Sánchez, Paul, additional, Santana-Ros, Toni, additional, Scheeres, Daniel J., additional, Scheirich, Peter, additional, Berk Senel, Cem, additional, Snodgrass, Colin, additional, Soldini, Stefania, additional, Souami, Damya, additional, Statler, Thomas S., additional, Street, Rachel, additional, Stubbs, Timothy J., additional, Sunshine, Jessica M., additional, Tan, Nicole J., additional, Tancredi, Gonzalo, additional, Tinsman, Calley L., additional, Tortora, Paolo, additional, Tusberti, Filippo, additional, Walker, James D., additional, Waller, C. Dany, additional, Wünnemann, Kai, additional, Zannoni, Marco, additional, and Zhang, Yun, additional

Published

2024

33. Dimorphos Orbit Determination from Mutual Events Photometry

Author

Scheirich, Peter, primary, Pravec, Petr, additional, Meyer, Alex J., additional, Agrusa, Harrison F., additional, Richardson, Derek C., additional, Chesley, Steven R., additional, Naidu, Shantanu P., additional, Thomas, Cristina, additional, and Moskovitz, Nicholas A., additional

Published

2024

34. CAPABILITIES OF EARTH-BASED RADAR FACILITIES FOR NEAR-EARTH ASTEROID OBSERVATIONS

Author

Naidu, Shantanu P, Benner, Lance AM, Margot, Jean-Luc, Busch, Michael W, and Taylor, Patrick A

Subjects

Space Sciences, Physical Sciences, minor planets, asteroids: general, techniques: radar astronomy, telescopes, astro-ph.EP, astro-ph.IM, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics

Abstract

We evaluated the planetary radar capabilities at Arecibo, the Goldstone 70 m DSS-14 and 34 m DSS-13 antennas, the 70 m DSS-43 antenna at Canberra, the Green Bank Telescope (GBT), and the Parkes Radio Telescope in terms of their relative sensitivities and the number of known near-Earth asteroids (NEAs) detectable per year in monostatic and bistatic configurations. In the 2015 calendar year, monostatic observations with Arecibo and DSS-14 were capable of detecting 253 and 131 NEAs respectively, with signal-to-noise ratios (SNRs) greater than 30/track. Combined, the two observatories were capable of detecting 276 NEAs. Of these, Arecibo detected 77 and Goldstone detected 32, or 30% and 24% of the numbers that were possible. The two observatories detected an additional 18 and 7 NEAs respectively, with SNRs of less than 30/track. This indicates that a substantial number of potential targets are not being observed. The bistatic configuration with DSS-14 transmitting and the GBT receiving was capable of detecting about 195 NEAs, or ~50% more than with monostatic observations at DSS-14. Most of the detectable asteroids were targets of opportunity that were discovered less than 15 days before the end of their observing windows. About 50% of the detectable asteroids have absolute magnitudes >25, which corresponds to diameters < ~30m.

Published

2016

35. Near-Earth Asteroid Satellite Spins Under Spin-Orbit Coupling

Author

Naidu, Shantanu P. and Margot, Jean-Luc

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We develop a fourth-order numerical integrator to simulate the coupled spin and orbital motions of two rigid bodies having arbitrary mass distributions under the influence of their mutual gravitational potential. We simulate the dynamics of components in well-characterized binary and triple near-Earth asteroid systems and use surface of section plots to map the possible spin configurations of the satellites. For asynchronous satellites, the analysis reveals large regions of phase space where the spin state of the satellite is chaotic. For synchronous satellites, we show that libration amplitudes can reach detectable values even for moderately elongated shapes. The presence of chaotic regions in the phase space has important consequences for the evolution of binary asteroids. It may substantially increase spin synchronization timescales, explain the observed fraction of asynchronous binaries, delay BYORP-type evolution, and extend the lifetime of binaries. The variations in spin rate due to large librations also affect the analysis and interpretation of lightcurve and radar observations., Comment: 12 pages, 11 figures, Published in AJ

Published

2014

36. NEAR-EARTH ASTEROID SATELLITE SPINS UNDER SPIN–ORBIT COUPLING

Author

Naidu, Shantanu P and Margot, Jean-Luc

Subjects

minor planets, asteroids: general, minor planets, asteroids: individual (2000 DP107, 1999 KW4, 2002, CE26, 2004 DC, 2003 YT1, Didymos, 1991 VH, 2001 SN263, 1994 CC, 1996 FG3), planets and satellites: dynamical evolution and stability, astro-ph.EP, asteroid, radar, spin, orbit, evolution, Astronomical and Space Sciences, Astronomy & Astrophysics

Abstract

We develop a fourth-order numerical integrator to simulate the coupled spin and orbital motions of two rigid bodies having arbitrary mass distributions under the influence of their mutual gravitational potential. We simulate the dynamics of components in well-characterized binary and triple near-Earth asteroid systems and use surface of section plots to map the possible spin configurations of the satellites. For asynchronous satellites, the analysis reveals large regions of phase space where the spin state of the satellite is chaotic. For synchronous satellites, we show that libration amplitudes can reach detectable values even for moderately elongated shapes. The presence of chaotic regions in the phase space has important consequences for the evolution of binary asteroids. It may substantially increase spin synchronization timescales, explain the observed fraction of asychronous binaries, delay BYORP-type evolution, and extend the lifetime of binaries. The variations in spin rate due to large librations also affect the analysis and interpretation of light curve and radar observations.

Published

2015

37. Radar Imaging and Physical Characterization of Near-Earth Asteroid (162421) 2000 ET70

Author

Naidu, Shantanu P., Margot, Jean-Luc, Busch, Michael W., Taylor, Patrick A., Nolan, Michael C., Brozovic, Marina, Benner, Lance A. M., Giorgini, Jon D., and Magri, Christopher

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We observed near-Earth asteroid (162421) 2000 ET70 using the Arecibo and Goldstone radar systems over a period of 12 days during its close approach to the Earth in February 2012. We obtained continuous wave spectra and range-Doppler images with range resolutions as fine as 15 m. Inversion of the radar images yields a detailed shape model with an effective spatial resolution of 100 m. The asteroid has overall dimensions of 2.6 km X 2.2 km X 2.1 km (5% uncertainties) and a surface rich with kilometer-scale ridges and concavities. This size, combined with absolute magnitude measurements, implies an extremely low albedo (~2%). It is a principal axis rotator and spins in a retrograde manner with a sidereal spin period of 8.96 +/- 0.01 hours. In terms of gravitational slopes evaluated at scales of 100 m, the surface seems mostly relaxed with over 99% of the surface having slopes less than 30 degrees, but there are some outcrops at the north pole that may have steeper slopes. Our precise measurements of the range and velocity of the asteroid, combined with optical astrometry, enables reliable trajectory predictions for this potentially hazardous asteroid in the interval 460-2813., Comment: 17 pages, 11 figures, accepted to Icarus

Published

2013

38. Near-Earth asteroid 2012 TC4 observing campaign: Results from a global planetary defense exercise

Author

Reddy, Vishnu, Kelley, Michael S., Farnocchia, Davide, Ryan, William H., Thomas, Cristina A., Benner, Lance A.M., Dotson, Jessie, Micheli, Marco, Brucker, Melissa J., Bus, Schelte J., Brozovic, Marina, Wheeler, Lorien, Abbasi, Viqar, Bauer, James M., Bonsall, Amber, Brown, Zarah L., Busch, Michael W., Chodas, Paul, Choi, Young-Jun, Erasmus, Nicolas, Fast, Kelly E., Faucher, John P., Fernandes, Rachel B., Ghigo, Frank D., Gilbank, David G., Giorgini, Jon D., Gustafsson, Annika, Hainaut, Olivier, Harris, Walter M., Jao, Joseph S., Johnson, Lindley S., Kareta, Theodore, Kim, Myung-Jin, Koschny, Detlef, Kramer, Emily A., Landis, Rob R., Laurin, Denis G., Larsen, Jeffrey A., Lee, Clement G., Lejoly, Cassandra, Lister, Tim, McMillan, Robert, Masiero, Joseph R., Mathias, Donovan, Mommert, Michael, Moon, Hong-Kyu, Moskovitz, Nicholas A., Naidu, Shantanu P., Nallapu, Ravi Teja, Niazi, Haris Khan, Noonan, John W., Polishook, David, Ryan, Eileen V., Schatz, Lauren, Scotti, James V., Sharkey, Benjamin, Shustov, Boris M., Sickafoose, Amanda A., Silva, Marc A., Slade, Martin A., Slick, Lindsay R., Snedeker, Lawrence G., Springmann, Alessondra, Tholen, David, Trilling, David E., Vodniza, Alberto Q., Wainscoat, Richard, Weryk, Robert, and Yoshikawa, Makoto

Published

2019

39. Assessing possible mutual orbit period change by shape deformation of Didymos after a kinetic impact in the NASA-led Double Asteroid Redirection Test

Author

Hirabayashi, Masatoshi, Davis, Alex B., Fahnestock, Eugene G., Richardson, Derek C., Michel, Patrick, Cheng, Andrew F., Rivkin, Andrew S., Scheeres, Daniel J., Chesley, Steven R., Yu, Yang, Naidu, Shantanu P., Schwartz, Stephen R., Benner, Lance A.M., Pravec, Petr, Stickle, Angela M., and Jutzi, Martin

Published

2019

40. Radar imaging and physical characterization of near-Earth Asteroid (162421) 2000 ET70

Author

Naidu, Shantanu P, Margot, Jean-Luc, Busch, Michael W, Taylor, Patrick A, Nolan, Michael C, Brozovic, Marina, Benner, Lance A.M., Giorgini, Jon D, and Magri, Christopher

Published

2013

41. The Perturbed Full Two-body Problem: Application to Post-DART Didymos

Author

Meyer, Alex J., primary, Agrusa, Harrison F., additional, Richardson, Derek C., additional, Daly, R. Terik, additional, Fuentes-Muñoz, Oscar, additional, Hirabayashi, Masatoshi, additional, Michel, Patrick, additional, Merrill, Colby C., additional, Nakano, Ryota, additional, Cheng, Andrew F., additional, Barbee, Brent, additional, Barnouin, Olivier S., additional, Chesley, Steven R., additional, Ernst, Carolyn M., additional, Gkolias, Ioannis, additional, Moskovitz, Nicholas A., additional, Naidu, Shantanu P., additional, Pravec, Petr, additional, Scheirich, Petr, additional, Thomas, Cristina A., additional, Tsiganis, Kleomenis, additional, and Scheeres, Daniel J., additional

Published

2023

42. Ejecta cloud from the AIDA space project kinetic impact on the secondary of a binary asteroid: I. mechanical environment and dynamical model

Author

Yu, Yang, Michel, Patrick, Schwartz, Stephen R., Naidu, Shantanu P., and Benner, Lance A.M.

Published

2017

43. Successful kinetic impact into an asteroid for planetary defence

Author

Daly, R. Terik, primary, Ernst, Carolyn M., additional, Barnouin, Olivier S., additional, Chabot, Nancy L., additional, Rivkin, Andrew S., additional, Cheng, Andrew F., additional, Adams, Elena Y., additional, Agrusa, Harrison F., additional, Abel, Elisabeth D., additional, Alford, Amy L., additional, Asphaug, Erik I., additional, Atchison, Justin A., additional, Badger, Andrew R., additional, Baki, Paul, additional, Ballouz, Ronald-L., additional, Bekker, Dmitriy L., additional, Bellerose, Julie, additional, Bhaskaran, Shyam, additional, Buratti, Bonnie J., additional, Cambioni, Saverio, additional, Chen, Michelle H., additional, Chesley, Steven R., additional, Chiu, George, additional, Collins, Gareth S., additional, Cox, Matthew W., additional, DeCoster, Mallory E., additional, Ericksen, Peter S., additional, Espiritu, Raymond C., additional, Faber, Alan S., additional, Farnham, Tony L., additional, Ferrari, Fabio, additional, Fletcher, Zachary J., additional, Gaskell, Robert W., additional, Graninger, Dawn M., additional, Haque, Musad A., additional, Harrington-Duff, Patricia A., additional, Hefter, Sarah, additional, Herreros, Isabel, additional, Hirabayashi, Masatoshi, additional, Huang, Philip M., additional, Hsieh, Syau-Yun W., additional, Jacobson, Seth A., additional, Jenkins, Stephen N., additional, Jensenius, Mark A., additional, John, Jeremy W., additional, Jutzi, Martin, additional, Kohout, Tomas, additional, Krueger, Timothy O., additional, Laipert, Frank E., additional, Lopez, Norberto R., additional, Luther, Robert, additional, Lucchetti, Alice, additional, Mages, Declan M., additional, Marchi, Simone, additional, Martin, Anna C., additional, McQuaide, Maria E., additional, Michel, Patrick, additional, Moskovitz, Nicholas A., additional, Murphy, Ian W., additional, Murdoch, Naomi, additional, Naidu, Shantanu P., additional, Nair, Hari, additional, Nolan, Michael C., additional, Ormö, Jens, additional, Pajola, Maurizio, additional, Palmer, Eric E., additional, Peachey, James M., additional, Pravec, Petr, additional, Raducan, Sabina D., additional, Ramesh, K. T., additional, Ramirez, Joshua R., additional, Reynolds, Edward L., additional, Richman, Joshua E., additional, Robin, Colas Q., additional, Rodriguez, Luis M., additional, Roufberg, Lew M., additional, Rush, Brian P., additional, Sawyer, Carolyn A., additional, Scheeres, Daniel J., additional, Scheirich, Petr, additional, Schwartz, Stephen R., additional, Shannon, Matthew P., additional, Shapiro, Brett N., additional, Shearer, Caitlin E., additional, Smith, Evan J., additional, Steele, R. Joshua, additional, Steckloff, Jordan K., additional, Stickle, Angela M., additional, Sunshine, Jessica M., additional, Superfin, Emil A., additional, Tarzi, Zahi B., additional, Thomas, Cristina A., additional, Thomas, Justin R., additional, Trigo-Rodríguez, Josep M., additional, Tropf, B. Teresa, additional, Vaughan, Andrew T., additional, Velez, Dianna, additional, Waller, C. Dany, additional, Wilson, Daniel S., additional, Wortman, Kristin A., additional, and Zhang, Yun, additional

Published

2023

44. Momentum transfer from the DART mission kinetic impact on asteroid Dimorphos

Author

Cheng, Andrew F., primary, Agrusa, Harrison F., additional, Barbee, Brent W., additional, Meyer, Alex J., additional, Farnham, Tony L., additional, Raducan, Sabina D., additional, Richardson, Derek C., additional, Dotto, Elisabetta, additional, Zinzi, Angelo, additional, Della Corte, Vincenzo, additional, Statler, Thomas S., additional, Chesley, Steven, additional, Naidu, Shantanu P., additional, Hirabayashi, Masatoshi, additional, Li, Jian-Yang, additional, Eggl, Siegfried, additional, Barnouin, Olivier S., additional, Chabot, Nancy L., additional, Chocron, Sidney, additional, Collins, Gareth S., additional, Daly, R. Terik, additional, Davison, Thomas M., additional, DeCoster, Mallory E., additional, Ernst, Carolyn M., additional, Ferrari, Fabio, additional, Graninger, Dawn M., additional, Jacobson, Seth A., additional, Jutzi, Martin, additional, Kumamoto, Kathryn M., additional, Luther, Robert, additional, Lyzhoft, Joshua R., additional, Michel, Patrick, additional, Murdoch, Naomi, additional, Nakano, Ryota, additional, Palmer, Eric, additional, Rivkin, Andrew S., additional, Scheeres, Daniel J., additional, Stickle, Angela M., additional, Sunshine, Jessica M., additional, Trigo-Rodriguez, Josep M., additional, Vincent, Jean-Baptiste, additional, Walker, James D., additional, Wünnemann, Kai, additional, Zhang, Yun, additional, Amoroso, Marilena, additional, Bertini, Ivano, additional, Brucato, John R., additional, Capannolo, Andrea, additional, Cremonese, Gabriele, additional, Dall’Ora, Massimo, additional, Deshapriya, Prasanna J. D., additional, Gai, Igor, additional, Hasselmann, Pedro H., additional, Ieva, Simone, additional, Impresario, Gabriele, additional, Ivanovski, Stavro L., additional, Lavagna, Michèle, additional, Lucchetti, Alice, additional, Epifani, Elena M., additional, Modenini, Dario, additional, Pajola, Maurizio, additional, Palumbo, Pasquale, additional, Perna, Davide, additional, Pirrotta, Simone, additional, Poggiali, Giovanni, additional, Rossi, Alessandro, additional, Tortora, Paolo, additional, Zannoni, Marco, additional, and Zanotti, Giovanni, additional

Published

2023

45. Orbital period change of Dimorphos due to the DART kinetic impact

Author

Thomas, Cristina A., primary, Naidu, Shantanu P., additional, Scheirich, Peter, additional, Moskovitz, Nicholas A., additional, Pravec, Petr, additional, Chesley, Steven R., additional, Rivkin, Andrew S., additional, Osip, David J., additional, Lister, Tim A., additional, Benner, Lance A. M., additional, Brozović, Marina, additional, Contreras, Carlos, additional, Morrell, Nidia, additional, Rożek, Agata, additional, Kušnirák, Peter, additional, Hornoch, Kamil, additional, Mages, Declan, additional, Taylor, Patrick A., additional, Seymour, Andrew D., additional, Snodgrass, Colin, additional, Jørgensen, Uffe G., additional, Dominik, Martin, additional, Skiff, Brian, additional, Polakis, Tom, additional, Knight, Matthew M., additional, Farnham, Tony L., additional, Giorgini, Jon D., additional, Rush, Brian, additional, Bellerose, Julie, additional, Salas, Pedro, additional, Armentrout, William P., additional, Watts, Galen, additional, Busch, Michael W., additional, Chatelain, Joseph, additional, Gomez, Edward, additional, Greenstreet, Sarah, additional, Phillips, Liz, additional, Bonavita, Mariangela, additional, Burgdorf, Martin J., additional, Khalouei, Elahe, additional, Longa-Peña, Penélope, additional, Rabus, Markus, additional, Sajadian, Sedighe, additional, Chabot, Nancy L., additional, Cheng, Andrew F., additional, Ryan, William H., additional, Ryan, Eileen V., additional, Holt, Carrie E., additional, and Agrusa, Harrison F., additional

Published

2023

46. Radar Observations and Characterization of Binary Near Earth Asteroid (35107) 1991 VH, A Flyby Target for the Proposed Janus Mission

Author

Naidu, Shantanu P, Margot, Jean-Luc, Benner, Lance A.M, Taylor, Patrick A, Nolan, Michael C, Magri, Chris, Brozovic, Marina, Busch, Michael W, Giorgini, Jon D, and Scheeres, Daniel J

Published

2019

47. Radar Observations and Characterization of Binary Near Earth Asteroid (35107) 1991 VH, A Flyby Target for the Proposed Janus Mission

Author

Scheeres, Daniel J, Giorgini, Jon D, Busch, Michael W, Brozovic, Marina, Magri, Chris, Nolan, Michael C, Taylor, Patrick A, Benner, Lance A.M, Margot, Jean-Luc, and Naidu, Shantanu P

Abstract

UNKNOWN

Published

2019

48. Anticipating the DART Impact: Orbit Estimation of Dimorphos Using a Simplified Model

Author

Naidu, Shantanu P., primary, Chesley, Steven R., additional, Farnocchia, Davide, additional, Moskovitz, Nick, additional, Pravec, Petr, additional, Scheirich, Petr, additional, Thomas, Cristina, additional, and Rivkin, Andrew S., additional

Published

2022

49. Fission and reconfiguration of bilobate comets as revealed by 67P/churyumov-gerasimenko

Author

Hirabayashi, Masatoshi, Scheeres, Daniel J., Chesley, Steven R., Marchi, Simone, McMahon, Jay W., Steckloff, Jordan, Mottola, Stefano, Naidu, Shantanu P., and Bowling, Timothy

Subjects

Astronomical research, Solar system -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

The solid, central part of a comet--its nucleus--is subject to destructive processes (1,2), which cause nuclei to split at a rate of about 0.01 per year per comet (3). These destructive events are due to a range of possible thermophysical effects (4); however, the geophysical expressions of these effects are unknown. Separately, over two-thirds of comet nuclei that have been imaged at high resolution show bilobate shapes (5), including the nucleus of comet 67P/Churyumov-Gerasimenko (67P), visited by the Rosetta spacecraft. Analysis of the Rosetta observations suggests that 67P's components were brought together at low speed after their separate formation (6). Here, we study the structure and dynamics of 67P's nucleus. We find that sublimation torques have caused the nucleus to spin up in the past to form the large cracks observed on its neck. However, the chaotic evolution of its spin state has so far forestalled its splitting, although it should eventually reach a rapid enough spin rate to do so. Once this occurs, the separated components will be unable to escape each other; they will orbit each other for a time, ultimately undergoing a low-speed merger that will result in a new bilobate configuration. The components of four other imaged bilobate nuclei have volume ratios that are consistent with a similar reconfiguration cycle, pointing to such cycles as a fundamental process in the evolution of short-period comet nuclei. It has been shown (7,8) that comets were not strong contributors to the so-called late heavy bombardment about 4 billion years ago. The reconfiguration process suggested here would preferentially decimate comet nuclei during migration to the inner solar system, perhaps explaining this lack of a substantial cometary flux., Along the neck of 67P's nucleus (the Hapi region) are two straight cracks, each a few hundred metres long and separated from each other by 750 metres (Fig. 1a, b) [...]

Published

2016

50. Apophis Planetary Defense Campaign

Author

Reddy, Vishnu, primary, Kelley, Michael S., additional, Dotson, Jessie, additional, Farnocchia, Davide, additional, Erasmus, Nicolas, additional, Polishook, David, additional, Masiero, Joseph, additional, Benner, Lance A. M., additional, Bauer, James, additional, Alarcon, Miguel R., additional, Balam, David, additional, Bamberger, Daniel, additional, Bell, David, additional, Barnardi, Fabrizio, additional, Bressi, Terry H., additional, Brozovic, Marina, additional, Brucker, Melissa J., additional, Buzzi, Luca, additional, Cano, Juan, additional, Cantillo, David, additional, Cennamo, Ramona, additional, Chastel, Serge, additional, Chingis, Omarov, additional, Choi, Young-Jun, additional, Christensen, Eric, additional, Denneau, Larry, additional, Dróżdż, Marek, additional, Elenin, Leonid, additional, Erece, Orhan, additional, Faggioli, Laura, additional, Falco, Carmelo, additional, Glamazda, Dmitry, additional, Graziani, Filippo, additional, Heinze, Aren N., additional, Holman, Matthew J., additional, Ivanov, Alexander, additional, Jacques, Cristovao, additional, Janse van Rensburg, Petro, additional, Kaiser, Galina, additional, Kamiński, Krzysztof, additional, Kamińska, Monika K., additional, Kaplan, Murat, additional, Kim, Dong-Heun, additional, Kim, Myung-Jin, additional, Kiss, Csaba, additional, Kokina, Tatiana, additional, Kuznetsov, Eduard, additional, Larsen, Jeffrey A., additional, Lee, Hee-Jae, additional, Lees, Robert C., additional, de León, Julia, additional, Licandro, Javier, additional, Mainzer, Amy, additional, Marciniak, Anna, additional, Marsset, Michael, additional, Mastaler, Ron A., additional, Mathias, Donovan L., additional, McMillan, Robert S., additional, Medeiros, Hissa, additional, Micheli, Marco, additional, Mokhnatkin, Artem, additional, Moon, Hong-Kyu, additional, Morate, David, additional, Naidu, Shantanu P., additional, Nastasi, Alessandro, additional, Novichonok, Artem, additional, Ogłoza, Waldemar, additional, Pál, András, additional, Pérez-Toledo, Fabricio, additional, Perminov, Alexander, additional, Petrescu, Elisabeta, additional, Popescu, Marcel, additional, Read, Mike T., additional, Reichart, Daniel E., additional, Reva, Inna, additional, Roh, Dong-Goo, additional, Rumpf, Clemens, additional, Satpathy, Akash, additional, Schmalz, Sergei, additional, Scotti, James V., additional, Serebryanskiy, Aleksander, additional, Serra-Ricart, Miquel, additional, Sonbas, Eda, additional, Szakáts, Robert, additional, Taylor, Patrick A., additional, Tonry, John L., additional, Tubbiolo, Andrew F., additional, Veres, Peter, additional, Wainscoat, Richard, additional, Warner, Elizabeth, additional, Weiland, Henry J., additional, Wells, Guy, additional, Weryk, Robert, additional, Wheeler, Lorien F., additional, Wiebe, Yulia, additional, Yim, Hong-Suh, additional, Żejmo, Michał, additional, Zhornichenko, Anastasiya, additional, Zoła, Stanisław, additional, and Michel, Patrick, additional

Published

2022