Your search keyword '"Virkki, A. K."' showing total 36 results

1. Asteroid 16 Psyche: Shape, Features, and Global Map

Author

Shepard, Michael K., de Kleer, Katherine, Cambioni, Saverio, Taylor, Patrick A., Virkki, Anne K., Rivera-Valentin, Edgard G., Sanchez-Vahamonde, Carolina Rodriguez, Zambrano-Marin, Luisa Fernanda, Magri, Christopher, Dunham, David, Moore, John, and Camarca, Maria

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We develop a shape model of asteroid 16 Psyche using observations acquired in a wide range of wavelengths: Arecibo S-band delay-Doppler imaging, Atacama Large Millimeter Array (ALMA) plane-of-sky imaging, adaptive optics (AO) images from Keck and the Very Large Telescope (VLT), and a recent stellar occultation. Our shape model has dimensions 278 (-4/+8) km x 238 (-4/+6) km x 171 (-1/+5) km, an effective spherical diameter Deff = 222 -1/+4 km, and a spin axis (ecliptic lon, lat) of (36 deg, -8 deg) +/- 2 deg. We survey all the features previously reported to exist, tentatively identify several new features, and produce a global map of Psyche. Using 30 calibrated radar echoes, we find Psyche's overall radar albedo to be 0.34 +/- 0.08 suggesting that the upper meter of regolith has a significant metal (i.e., Fe-Ni) content. We find four regions of enhanced or complex radar albedo, one of which correlates well with a previously identified feature on Psyche, and all of which appear to correlate with patches of relatively high optical albedo. Based on these findings, we cannot rule out a model of Psyche as a remnant core, but our preferred interpretation is that Psyche is a differentiated world with a regolith composition analogous to enstatite or CH/CB chondrites and peppered with localized regions of high metal concentrations. The most credible formation mechanism for these regions is ferrovolcanism as proposed by Johnson et al. (Nature Astronomy vol 4, January 2020, 41-44)., Comment: 45 pages, 10 embedded figures, 6 tables

Published

2021

2. The Future Of The Arecibo Observatory: The Next Generation Arecibo Telescope

Author

Roshi, D. Anish, Aponte, N., Araya, E., Arce, H., Baker, L. A., Baan, W., Becker, T. M., Breakall, J. K., Brown, R. G., Brum, C. G. M., Busch, M., Campbell, D. B., Cohen, T., Cordova, F., Deneva, J. S., Devogele, M., Dolch, T., Fernandez-Rodriguez, F. O., Ghosh, T., Goldsmith, P. F., Gurvits, L. I., Haynes, M., Heiles, C., Hessel, J. W. T., Hickson, D., Isham, B., Kerr, R. B., Kelly, J., Kiriazes, J. J., Lautenbach, J., Lebron, M., Lewandowska, N., Magnani, L., Manoharan, P. K., Margot, J. L., Marshall, S. E., McGilvray, A. K., Mendez, A., Minchin, R., Negron, V., Nolan, M. C., Olmi, L., Paganelli, F., Palliyaguru, N. T., Pantoja, C. A., Paragi, Z., Parshley, S. C., Peek, J. E. G., Perera, B. B. P., Perillat, P., Pinilla-Alonso, N., Quintero, L., Radovan, H., Raizada, S., Robishaw, T., Route, M., Salter, C. J., Santoni, A., Santos, P., Sau, S., Selvaraj, D., Smith, A. J., Sulzer, M., Vaddi, S., Vargas, F., Venditti, F. C. F., Venkataraman, A., Verkouter, H., Virkki, A. K., Vishwas, A., Weinreb, S., Werthimer, D., Wolszczan, A., and Zambrano-Marin, L. F.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Atmospheric and Oceanic Physics, Physics - Instrumentation and Detectors

Abstract

The Arecibo Observatory (AO) is a multidisciplinary research and education facility that is recognized worldwide as a leading facility in astronomy, planetary, and atmospheric and space sciences. AO's cornerstone research instrument was the 305-m William E. Gordon telescope. On December 1, 2020, the 305-m telescope collapsed and was irreparably damaged. In the three weeks following the collapse, AO's scientific and engineering staff and the AO users community initiated extensive discussions on the future of the observatory. The community is in overwhelming agreement that there is a need to build an enhanced, next-generation radar-radio telescope at the AO site. From these discussions, we established the set of science requirements the new facility should enable. These requirements can be summarized briefly as: 5 MW of continuous wave transmitter power at 2 - 6 GHz, 10 MW of peak transmitter power at 430 MHz (also at 220MHz under consideration), zenith angle coverage 0 to 48 deg, frequency coverage 0.2 to 30 GHz and increased Field-of-View. These requirements determine the unique specifications of the proposed new instrument. The telescope design concept we suggest consists of a compact array of fixed dishes on a tiltable, plate-like structure with a collecting area equivalent to a 300m dish. This concept, referred to as the Next Generation Arecibo Telescope (NGAT), meets all of the desired specifications and provides significant new science capabilities to all three research groups at AO. This whitepaper presents a sample of the wide variety of the science that can be achieved with the NGAT, the details of the telescope design concept and the need for the new telescope to be located at the AO site. We also discuss other AO science activities that interlock with the NGAT in the white paper., Comment: 82 pages (executive summary 10 pages), 21 figures, Arecibo observatory white paper (Updated with the complete author list and minor edits)

Published

2021

3. Pathways to Sustainable Planetary Science

Author

Ćuk, Matija, Virkki, Anne K., Kohout, Tomáš, Lellouch, Emmanuel, and Lissauer, Jack J.

Subjects

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

Abstract

Climate change is a major impending threat to the future of humanity. According to the International Panel on Climate Change (IPCC), our emissions are estimated to have caused 0.8 deg C-1.2 deg C of anthropogenic global warming (AGW) above pre-industrial levels. AGW is likely to reach 1.5 degrees C between 2030 and 2052 if it continues to increase at the current rate. As the climate change is driven by the release of carbon dioxide and other greenhouse gases (GHG) into the atmosphere, there is a broad consensus that the mitigation of climate change requires transition to low GHG emission energy sources, technologies and practices. Implementing such changes systematically from individual to community-wide scales together with the resulting cultural changes and leadership towards environmental consciousness and responsibility are crucial to mitigate the looming damage of AGW. Given planetary scientists' wide recognition of the realities of climate change, and the need for us to maintain credibility by leading by example, it is appropriate to make own professional behavior more environmentally responsible. While scientists are few in numbers, and planetary scientists far fewer, high volumes of academic travel to conferences, panels, colloquia, and research collaboration visits together with extensive use of large, energetically demanding infrastructures make the "carbon footprint" of scientists much higher than that of an average citizen. This White Paper focuses on how modifying our activities, particularly associated with academic travel, can affect the carbon footprint of the planetary science community, and it makes recommendations on how the community and the funding agencies could best participate in the cultural change required to mitigate the damage that AGW will cause., Comment: Planetary Science and Astrobiology Decadal Survey 2023-2032 White Paper. Asking for endorsements

Published

2020

4. Linking the Solar System and Extrasolar Planetary Systems with Radar Astronomy: Infrastructure for 'Ground Truth' Comparison

Author

Lazio, Joseph, Bonsall, Amber, Brozovic, Marina, Giorgini, Jon D., O'Neil, Karen, Rivera-Valentin, Edgard, Virkki, Anne K., Cordova, Francisco, Busch, Michael, Campbell, Bruce A., Edwards, P. G., Fernandez, Yanga R., Kruzins, Ed, Pinilla-Alonso, Noemi, Slade, Martin A., and Venditti, F. C. F.

Subjects

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

Abstract

Planetary radars have obtained unique science measurements about solar system bodies and they have provided orbit determinations allowing spacecraft to be navigated throughout the solar system. Notable results have been on Venus, Earth's "twin," and small bodies, which are the constituents of the Sun's debris disk. Together, these results have served as "ground truth" from the solar system for studies of extrasolar planets. The Nation's planetary radar infrastructure, indeed the world's planetary radar infrastructure, is based on astronomical and deep space telecommunications infrastructure, namely the radar transmitters at the Arecibo Observatory and the Goldstone Solar System Radar, part of NASA's Deep Space Network, along with the Green Bank Telescope as a receiving element. This white paper summarizes the state of this infrastructure and potential technical developments that should be sustained in order to enable continued studies of solar system bodies for comparison and contrast with extrasolar planetary systems. Because the planetary radar observations leverage existing infrastructure largely developed for other purposes, only operations and maintenance funding is required, though modest investments could yield more reliable systems; in the case of the Green Bank Telescope, additional funding for operations is required., Comment: 9 pages, 3 figures; Astro2020 Activities, Projects, or State of the Profession Consideration white paper

Published

2019

5. Astro2020 Activities and Projects White Paper: Arecibo Observatory in the Next Decade

Author

Roshi, D. Anish, Anderson, L. D., Araya, E., Balser, D., Brisken, W., Brum, C., Campbell, D., Chatterjee, S., Churchwell, E., Condon, J., Cordes, J., Cordova, F., Fernandez, Y., Gago, J., Ghosh, T., Goldsmith, P. F., Heiles, C., Hickson, D., Jeffs, B., Jones, K. M., Lautenbach, J., Lewis, B. M., Lynch, R. S., Manoharan, P. K., Marshall, S., Minchin, R., Palliyaguru, N. T., Perera, B. B. P., Perillat, P., Pinilla-Alonso, N., Pisano, D. J., Quintero, L., Raizada, S., Ransom, S. M., Fernandez-Rodriguez, F. O., Salter, C. J., Santos, P., Sulzer, M., Taylor, P. A., Venditti, F. C. F., Venkataraman, A., Virkki, A. K., Wolszczan, A., Womack, M., and Zambrano-Marin, L. F.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The white paper discusses Arecibo Observatory's plan for facility improvements and activities over the next decade. The facility improvements include: (a) improving the telescope surface, pointing and focusing to achieve superb performance up to ~12.5 GHz; (b) equip the telescope with ultrawide-band feeds; (c) upgrade the instrumentation with a 4 GHz bandwidth high dynamic range digital link and a universal backend and (d) augment the VLBI facility by integrating the 12m telescope for phase referencing. These upgrades to the Arecibo telescope are critical to keep the national facility in the forefront of research in radio astronomy while maintaining its dominance in radar studies of near-Earth asteroids, planets and satellites. In the next decade, the Arecibo telescope will play a synergistic role with the upcoming facilities such as ngVLA, SKA and the now commissioned FAST telescope. Further, the observatory will be actively engaged in mentoring and training programs for students from a diverse background., Comment: Submitted as an Activities and Projects White Paper for the Astro2020 decadal survey (13 pages, 3 figures, 1 table)

Published

2019

6. Arecibo Radar Observations of Near-Earth Asteroid (3200) Phaethon During the 2017 Apparition

Author

Taylor, Patrick A., Rivera-Valentin, Edgard G., Benner, Lance A. M., Marshall, Sean E., Virkki, Anne K., Venditti, Flaviane C. F., Zambrano-Marin, Luisa F., Bhiravarasu, Sriram S., Aponte-Hernandez, Betzaida, Sanchez-Vahamonde, Carolina Rodriguez, and Giorgini, Jon D.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

We report Arecibo S-band (2380 MHz; 12.6 cm) radar observations of near-Earth asteroid (3200) Phaethon during the December 2017 apparition when Phaethon passed within 0.07 au of Earth. Radar images with a resolution of 75 m per pixel reveal a roughly spheroidal shape more than 6 km in diameter at the equator with several discernible surface features hundreds of meters in extent. These include a possible crater more than 1 km across located below 30$^{\circ}$ latitude and a roughly 600-m radar-dark region near one of the poles. Overall, the radar images of Phaethon are reminiscent of those of (101955) Bennu, target of the OSIRIS-REx mission. As such, the shape of Phaethon is suspected to have an equatorial ridge similar to the top-shaped models of several other radar-observed near-Earth asteroids as well as the optical images of (162173) Ryugu returned by the Hayabusa2 spacecraft. Preliminary analysis of the radar data finds no satellites and gives no indication of a dusty coma at the time of these observations., Comment: 16 pages, 2 tables, 5 figures, accepted to Planetary and Space Sciences special issue on Phaethon and Meteoroids

Published

2019

7. Light scattering model for small space debris particles

Author

Peltoniemi, Jouni I., Zubko, Nataliya, Virkki, Anne K., Gritsevich, Maria, Moilanen, Jarmo, Roulet, Jean-Christophe, Nguyen, David, Mitev, Valentin, Putzar, Robin, Watson, Erkai, Schimmerohn, Martin, Penttilä, Antti, Muinonen, Karri, and Millinger, Mark

Published

2022

8. Near-earth asteroid (66391) Moshup (1999 KW4) observing campaign: Results from a global planetary defense characterization exercise

Author

Reddy, Vishnu, Kelley, Michael S., Dotson, Jessie, Landis, Rob R., McGraw, Lauren E., Micheli, Marco, Moskovitz, Nicholas A., Sanchez, Juan A., Taylor, Patrick A., Wheeler, Lorien, Bauer, James M., Brucker, Melissa J., Devogèle, Maxime, Emery, Joshua P., Hainaut, Olivier, Hickson, Dylan C., Koschny, Detlef, Larsen, Jeffrey A., Marshall, Sean E., McMillan, Robert, Skiff, Brian A., Venditti, Flaviane C.F., Virkki, Anne K., Yang, Bin, and Zambrano-Marin, Luisa F.

Published

2022

9. 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

10. Toward a European Facility for Ground-Based Radar Observations of Near-Earth Objects

Author

Pupillo, Giuseppe, primary, Righini, Simona, additional, Orosei, Roberto, additional, Bortolotti, Claudio, additional, Maccaferri, Giuseppe, additional, Roma, Mauro, additional, Mastrogiuseppe, Marco, additional, Pisanu, Tonino, additional, Schirru, Luca, additional, Cicalò, Stefano, additional, Tripodo, Antonio, additional, Harju, Jorma, additional, Penttilä, Antti, additional, Virkki, Anne K., additional, Bach, Uwe, additional, Kraus, Alexander, additional, Margheri, Alessio, additional, Ghiani, Riccardo, additional, Iacolina, Maria N., additional, Valente, Giuseppe, additional, Koschny, Detlef, additional, Moissl, Richard, additional, and Sessler, Gunther, additional

Published

2023

11. Toward a European Facility for Ground-Based Radar Observations of Near-Earth Objects.

Author

Pupillo, Giuseppe, Righini, Simona, Orosei, Roberto, Bortolotti, Claudio, Maccaferri, Giuseppe, Roma, Mauro, Mastrogiuseppe, Marco, Pisanu, Tonino, Schirru, Luca, Cicalò, Stefano, Tripodo, Antonio, Harju, Jorma, Penttilä, Antti, Virkki, Anne K., Bach, Uwe, Kraus, Alexander, Margheri, Alessio, Ghiani, Riccardo, Iacolina, Maria N., and Valente, Giuseppe

Subjects

NEAR-Earth objects, RADAR, BISTATIC radar, ASTROMETRY, RADIO telescopes, TRANSMITTING antennas

Abstract

In this work, we present the preliminary results of radar observations of Near-Earth Objects (NEOs) carried out by European radio telescopes in the framework of the European Space Agency (ESA) project "NEO observation concepts for radar systems", aimed at deriving the functional requirements of a planetary radar system, evaluating the available European assets to perform NEO radar observations, and carrying out test radar campaigns. In the first part of the project, we executed the performance analysis of a possible European planetary radar system. Instrumental features, as much as issues like the impact of weather conditions on signal propagation at different radio frequencies, were considered. This paper focused on the test campaigns, performed in the years 2021–2022 in collaboration with the Jet Propulsion Laboratory (JPL), which led to the observation of several asteroids including 2021 AF8, (4660) Nereus, and 2005 LW3, which allowed us to derive astrometric measurements, as well as to measure physical properties, such as rotation periods, and observe how one of the targets is actually a binary asteroid. The obtained results demonstrated that European radio astronomical dishes, although employed only as receivers (in bistatic or multistatic configurations) and for a limited amount of time, are able to provide a significant contribution to the constitution of a European network to increase the opportunities for NEO monitoring and studies, if a transmitting antenna—equipped with a suitable high-power transmitter—were made available. [ABSTRACT FROM AUTHOR]

Published

2024

12. Radar Reconnaissance of 99942 Apophis

Author

Howell, E. S, Nolan, M.C, Marshall, S. E, Venditti, F. C. F, Virkki, A. K, Rivera-Valentin, E. G, Taylor, P. A, Giorgini, J. D, Busch, M. W, Naidu, S. P, Benner, L. A. M, and Brozovic, Marina

Abstract

UNKNOWN

Published

2020

13. Radar Reconnaissance of 99942 Apophis

Author

Brozovic, Marina, Benner, L. A. M, Naidu, S. P, Busch, M. W, Giorgini, J. D, Taylor, P. A, Rivera-Valentin, E. G, Virkki, A. K, Venditti, F. C. F, Marshall, S. E, Nolan, M.C, and Howell, E. S

Published

2020

14. Planetary Radar—State-of-the-Art Review.

Author

Virkki, Anne K., Neish, Catherine D., Rivera-Valentín, Edgard G., Bhiravarasu, Sriram S., Hickson, Dylan C., Nolan, Michael C., and Orosei, Roberto

Subjects

*GROUND penetrating radar, *ASTEROIDS, *RADAR, *NEAR-earth asteroids, *HUMAN space flight, *PLANETARY exploration, *PLANETARY observations

Abstract

Planetary radar observations have provided invaluable information on the solar system through both ground-based and space-based observations. In this overview article, we summarize how radar observations have contributed in planetary science, how the radar technology as a remote-sensing method for planetary exploration and the methods to interpret the radar data have advanced in the eight decades of increasing use, where the field stands in the early 2020s, and what are the future prospects of the ground-based facilities conducting planetary radar observations and the planned spacecraft missions equipped with radar instruments. The focus of the paper is on radar as a remote-sensing technique using radar instruments in spacecraft orbiting planetary objects and in Earth-based radio telescopes, whereas ground-penetrating radar systems on landers are mentioned only briefly. The key scientific developments are focused on the search for water ice in the subsurface of the Moon, which could be an invaluable in situ resource for crewed missions, dynamical and physical characterization of near-Earth asteroids, which is also crucial for effective planetary defense, and a better understanding of planetary geology. [ABSTRACT FROM AUTHOR]

Published

2023

15. Arecibo Planetary Radar Observations of Near-Earth Asteroids: 2017 December–2019 December

Author

Virkki, Anne K., primary, Marshall, Sean E., additional, Venditti, Flaviane C. F., additional, Zambrano-Marín, Luisa F., additional, Hickson, Dylan C., additional, McGilvray, Anna, additional, Taylor, Patrick A., additional, Rivera-Valentín, Edgard G., additional, Devogèle, Maxime, additional, Franco Díaz, Eframir, additional, Bhiravarasu, Sriram S., additional, Aponte Hernández, Betzaida, additional, Rodriguez Sánchez-Vahamonde, Carolina, additional, Nolan, Michael C., additional, Perillat, Phil, additional, Cabrera, Israel, additional, González, Elliot, additional, Padilla, Daniel, additional, Negrón, Victor, additional, Marrero, Juan, additional, Lebrón, Johbany, additional, Bagué, Adrian, additional, Jiménez, Francisco, additional, López-Oquendo, Andy, additional, Repp, Daniel, additional, McGlasson, Riley A., additional, Presler-Marshall, Brynn, additional, Howell, Ellen S., additional, Margot, Jean-Luc, additional, and Prabhu Desai, Sanjana, additional

Published

2022

16. Radar and Optical Characterization of Near-Earth Asteroid 2019 OK

Author

Zambrano-Marin, Luisa Fernanda, primary, Howell, Ellen S., additional, Taylor, Patrick A., additional, Marshall, Sean E., additional, Devogèle, Maxime, additional, Virkki, Anne K., additional, Hickson, Dylan C., additional, Rivera-Valentín, Edgard G., additional, Venditti, Flaviane C. F., additional, and Giorgini, Jon D., additional

Published

2022

17. Arecibo S-band Radar Characterization of Local-scale Heterogeneities within Mercury’s North Polar Deposits

Author

Rivera-Valentín, Edgard G., primary, Meyer, Heather M., additional, Taylor, Patrick A., additional, Mazarico, Erwan, additional, Bhiravarasu, Sriram S., additional, Virkki, Anne K., additional, Nolan, Michael C., additional, Chabot, Nancy L., additional, and Giorgini, Jon D., additional

Published

2022

18. Radar and Lightcurve Observations and a Physical Model of Potentially Hazardous Asteroid 1981 Midas

Author

McGlasson, Riley A., primary, Marshall, Sean E., additional, Venditti, Flaviane C. F., additional, Naidu, Shantanu P., additional, Benner, Lance A. M., additional, Brozović, Marina, additional, Giorgini, Jon D., additional, Taylor, Patrick A., additional, Aponte, Betzaida, additional, Virkki, Anne K., additional, Harris, Alan W., additional, Young, James W., additional, Husárik, Marek, additional, Wells, Guy, additional, Bamberger, Daniel, additional, and Tobak, Jeff, additional

Published

2022

19. More Bucks for the Bang: New Space Solutions, Impact Tourism and one Unique Science & Engineering Opportunity at T-6 Months and Counting

Author

Grundmann, Jan Thimo, Borella, Laura, Ceriotti, Matteo, Chand, Suditi, Cordero, Federico, Dachwald, Bernd, Fexer, Sebastian, Fuglesang, Christer, Garcia de Herreros Miciano, María, Grimm, Christian, Hendrikse, Jeffrey, Hercik, David, Herique, Alain, Hillebrandt, Martin, Ho, Tra-Mi, Kesseler, Lars, Laabs, M., Lange, Caroline, Lange, Michael, Lichtenheldt, Roy, Nyman, Erik Lindblad, McInnes, Colin, Moore, Iain, Peloni, Alessandro, Plettemeier, Dirk, Quantius, Dominik, Ricci, Leonardo, Seefeldt, Patric, Tibert, Gunnar, Venditti, Flaviane C. F., Vergaaij, Merel, Vial, Simon, Viavattene, Giulia, Virkki, Anne K., Wu, Jingyang, and Zander, Martin E.

Subjects

Near-Earth Object, new space, responsive space, disaster preparedness, hazardous asteroid mitigation

Published

2021

20. MASCOT Asteroid Nanolanders: From Ryugu and Didymoon towards Future Missions at ‘2021 PDC’, Apophis 2029, and Beyond

Author

Lange, Caroline, Ho, Tra-Mi, Grundmann, Jan Thimo, Borella, Laura, Chand, Suditi, Cordero, Federico, Fexer, Sebastian, Grimm, Christian, Hendrikse, Jeffrey, Hercik, David, Herique, Alain, Kesseler, Lars, Laabs, M., Lange, Michael, Lichtenheldt, Roy, Plettemeier, D., Quantius, Dominik, Venditti, Flaviane C. F., Virkki, Anne K., Ailor, William H, Barbee, Brent, Drolshagen, Gerhard, Karl, Alex, Melamed, Nahum, Cheng, Andy, Tantardini, Marco, and Vardaxis, George

Subjects

Funktionsleichtbau, Raumfahrt-Systemdynamik, Near-Earth Object, nanolander, re-use strategies, Land und Explorationstechnologie, Systementwicklung und Projektbüro, planetary science radar, Systemanalyse Raumsegment, MASCOT2

Abstract

For now, the Planetary Defense Conference Exercise 2021's incoming fictitious(!) asteroid, 2021 PDC, seems headed for impact on October 20th, 2021, exactly 6 months after its discovery. Today (Monday, April 26th, 2021), the impact probability is 5%, in a steep rise from 1 in 2500 upon discovery six days ago. We all know how these things end. Or do we? Unless somebody wants to keep civil defense very busy very soon, the chance is 95% that it will not hit; instead fly by closely to Earth, swing by to a new orbit that takes it away essentially forever or back again sooner or later through a keyhole, for a re-play at different odds. This is where our story starts and the story sounds familiar: season's greetings from 2004 MN4, now better known as (99942) Apophis. One more thing is similar: the close fly-by is an easy launch opportunity to 'jump aboard' that potentially hazardous asteroid for planetary science and tracking of longterm Yarkovsky-shifted keyhole resonant return risks. Indeed, missions are currently being discussed to launch during the 2029 fly-by of Apophis to rendezvous and investigate it closely right after. Others strive for an earlier launch to rendezvous well before, to observe all of the close fly-by at Earth and what it might do to a likely delicate rubble pile asteroid. Presently, this is an unlikely if not impossible option for sudden encounters like 2021 PDC with a lead time of months. But when asteroid mining (...possibly the other ...-not-if of asteroids?) takes off in the same manner as low Earth orbit communications satellites, this option may become a reality. But for now, even if a suitable planetary mission were serendipitously ready atop a suitable launch vehicle, could you get it an asteroid lander within 6 months? Surprisingly, this option existed between late 2014 and late 2018 when the MASCOT Qualification Model turned Flight Spare was kept fully integrated and flight ready for on-ground testing to prepare for the Flight Model's brief but complete mission on Ryugu with JAXA's highly successful HAYABUSA2 probe. At the same time, the MASCOT2 detailed design study for ESA's former AIM mission within the common NASA-ESA AIDA mission to (65803) Didymos and its moonlet, Dimorphos (then affectionately known as 'Didymoon'), paved the way for long-life MASCOTs, many of which have been discussed and studied since. The thoughtful design of MASCOT’s hardware and software allowed for a very high degree of re-use and flexibility regarding scientific payloads. MASCOT2 was to investigate the interior of Didymoon by Low-Frequency Radar. Close encounters like Apophis' offer unique opportunities for Earth-based planetary radar assets to work with spacecraft near and landers on the passing asteroid. We present a range of options for radar- and composition-oriented long-life MASCOT variants - to be delivered to the surfaces of the respective asteroid bodies - for the presently most likely near miss of 2021 PDC and the most certain close fly-by of (99942) Apophis on Friday, April 13th, 2029.

Published

2021

21. Asteroid 16 Psyche: Shape, Features, and Global Map

Author

Shepard, Michael K., primary, de Kleer, Katherine, additional, Cambioni, Saverio, additional, Taylor, Patrick A., additional, Virkki, Anne K., additional, Rívera-Valentin, Edgard G., additional, Rodriguez Sanchez-Vahamonde, Carolina, additional, Fernanda Zambrano-Marin, Luisa, additional, Magri, Christopher, additional, Dunham, David, additional, Moore, John, additional, and Camarca, Maria, additional

Published

2021

22. The Future Of The Arecibo Observatory: The Next Generation Arecibo Telescope

Author

Anish Roshi, D., Aponte, N., Araya, E., Arce, H., Baker, L. A., Baan, W., Becker, T. M., Breakall, J. K., Brown, R. G., Brum, C. G. M., Busch, M., Campbell, D. B., Cohen, T., Cordova, F., Deneva, J. S., Devogele, M., Dolch, T., Fernandez-Rodriguez, F. O., Ghosh, T., Goldsmith, P. F., Gurvits, L. I., Haynes, M., Heiles, C., Hessel, J. W. T., Hickson, D., Isham, B., Kerr, R. B., Kelly, J., Kiriazes, J. J., Lautenbach, J., Lebron, M., Lewandowska, N., Magnani, L., Manoharan, P. K., Margot, J. L., Marshall, S. E., McGilvray, A. K., Mendez, A., Minchin, R., Negron, V., Nolan, M. C., Olmi, L., Paganelli, F., Palliyaguru, N. T., Pantoja, C. A., Paragi, Z., Parshley, S. C., Peek, J. E. G., Perera, B. B. P., Perillat, P., Pinilla-Alonso, N., Quintero, L., Radovan, H., Raizada, S., Robishaw, T., Route, M., Salter, C. J., Santoni, A., Santos, P., Sau, S., Selvaraj, D., Smith, A. J., Sulzer, M., Vaddi, S., Vargas, F., Venditti, F. C. F., Venkataraman, A., Verkouter, H., Virkki, A. K., Vishwas, A., Weinreb, S., Werthimer, D., Wolszczan, A., Zambrano-Marin, L. F., Anish Roshi, D., Aponte, N., Araya, E., Arce, H., Baker, L. A., Baan, W., Becker, T. M., Breakall, J. K., Brown, R. G., Brum, C. G. M., Busch, M., Campbell, D. B., Cohen, T., Cordova, F., Deneva, J. S., Devogele, M., Dolch, T., Fernandez-Rodriguez, F. O., Ghosh, T., Goldsmith, P. F., Gurvits, L. I., Haynes, M., Heiles, C., Hessel, J. W. T., Hickson, D., Isham, B., Kerr, R. B., Kelly, J., Kiriazes, J. J., Lautenbach, J., Lebron, M., Lewandowska, N., Magnani, L., Manoharan, P. K., Margot, J. L., Marshall, S. E., McGilvray, A. K., Mendez, A., Minchin, R., Negron, V., Nolan, M. C., Olmi, L., Paganelli, F., Palliyaguru, N. T., Pantoja, C. A., Paragi, Z., Parshley, S. C., Peek, J. E. G., Perera, B. B. P., Perillat, P., Pinilla-Alonso, N., Quintero, L., Radovan, H., Raizada, S., Robishaw, T., Route, M., Salter, C. J., Santoni, A., Santos, P., Sau, S., Selvaraj, D., Smith, A. J., Sulzer, M., Vaddi, S., Vargas, F., Venditti, F. C. F., Venkataraman, A., Verkouter, H., Virkki, A. K., Vishwas, A., Weinreb, S., Werthimer, D., Wolszczan, A., and Zambrano-Marin, L. F.

Abstract

The Arecibo Observatory (AO) is a multidisciplinary research and education facility that is recognized worldwide as a leading facility in astronomy, planetary, and atmospheric and space sciences. AO's cornerstone research instrument was the 305-m William E. Gordon telescope. On December 1, 2020, the 305-m telescope collapsed and was irreparably damaged. In the three weeks following the collapse, AO's scientific and engineering staff and the AO users community initiated extensive discussions on the future of the observatory. The community is in overwhelming agreement that there is a need to build an enhanced, next-generation radar-radio telescope at the AO site. From these discussions, we established the set of science requirements the new facility should enable. These requirements can be summarized briefly as: 5 MW of continuous wave transmitter power at 2 - 6 GHz, 10 MW of peak transmitter power at 430 MHz (also at 220MHz under consideration), zenith angle coverage 0 to 48 deg, frequency coverage 0.2 to 30 GHz and increased Field-of-View. These requirements determine the unique specifications of the proposed new instrument. The telescope design concept we suggest consists of a compact array of fixed dishes on a tiltable, plate-like structure with a collecting area equivalent to a 300m dish. This concept, referred to as the Next Generation Arecibo Telescope (NGAT), meets all of the desired specifications and provides significant new science capabilities to all three research groups at AO. This whitepaper presents a sample of the wide variety of the science that can be achieved with the NGAT, the details of the telescope design concept and the need for the new telescope to be located at the AO site. We also discuss other AO science activities that interlock with the NGAT in the white paper.

Published

2021

23. The Next-Generation Ground-Based Planetary Radar

Author

Lazio, Joseph, primary, Virkki, Anne K., additional, Pinilla-Alonso, Noemi, additional, Benner, L. A. M., additional, Brozovic, M., additional, Butler, B. J., additional, Campbell, B. A., additional, Cordova, F., additional, Kleer, K. de, additional, Edwards, P. G., additional, Eubanks, T. M., additional, Fernandez, Y. R., additional, Giorgini, J. D., additional, Kruzins, E., additional, Margot, J. L., additional, Mainzer, A., additional, Marshall, S. E., additional, Paganelli, F., additional, Raymond, C. A., additional, Taylor, P. A., additional, Rivera-Valentín, E., additional, Slade, M. A., additional, and Venditti, F. C. F., additional

Published

2021

24. Pathways to Sustainable Planetary Science

Author

Cuk, Matija, primary, Virkki, Anne K., additional, Kohout, Tomas, additional, Lellouch, Emmanuel, additional, and Lissauer, Jack J., additional

Published

2021

25. The Future of Planetary Defense in the Era of Advanced Surveys

Author

Mainzer, Amy, primary, Abell, P., additional, Bannister, Michele T., additional, Barbee, B., additional, Barnes, J., additional, III, J. F. Bell,, additional, Benner, L., additional, Betts, B., additional, Bose, Maitrayee, additional, Bottke, W., additional, Britt, D., additional, Brozović, M., additional, Bruckner, M., additional, Busch, Michael W., additional, Carey, S., additional, Castillo-Rogez, J., additional, Chesley, J., additional, Christensen, E., additional, Chodas, P., additional, Cotto-Figueroa, D., additional, Delbó, M., additional, Daly, R. T., additional, Dotson, J., additional, Eisenhardt, P., additional, Fernandez, Y. R., additional, Fevig, Ronald A., additional, Grav, T., additional, Greenstreet, S., additional, Gritsevich, M., additional, Hammel, Heidi B., additional, Harris, A., additional, Harris, W., additional, Hickson, D., additional, Hughson, Kynan, additional, Ivezić, Željko, additional, Jha, Devanshu, additional, Jones, Lynne, additional, Jurić, Mario, additional, Kacar, B., additional, Lauretta, D., additional, Lazio, Joseph, additional, Lopes, Rosaly M. C., additional, Marchis, F., additional, Marshall, Sean E., additional, Masiero, J., additional, Mathias, D., additional, McMillan, R. S., additional, McMurtry, C., additional, Michel, P., additional, Naidu, S., additional, Nolan, M. C., additional, Okada, T., additional, Pipher, J. L., additional, Raymond, Carol, additional, Rivera-Valentín, E., additional, Rivkin, A., additional, Schambeau, C. A., additional, Scheeres, D., additional, Scully, Jennifer, additional, Sonnett, S., additional, Spahr, T., additional, Stern, A., additional, Swindle, T., additional, Taylor, P., additional, Takir, D., additional, Telus, M., additional, Thomas, C., additional, Venditti, F. C. F., additional, Virkki, Anne K., additional, Wong, A., additional, and Wright, E. L., additional

Published

2021

26. Near-Earth Objects

Author

Nolan, Michael, primary, Michel, Patrick, additional, Venditti, Flaviane C. F., additional, Samarasinha, Nalin, additional, Sugita, Seiji, additional, Perry, Mark E., additional, Daly, R. Terik, additional, Binzel, Richard P., additional, Sanchez-Vahamonde, Carolina Rodriguez, additional, Devogele, Maxime, additional, Asphaug, Erik, additional, Hickson, Dylan C., additional, Masiero, Joseph, additional, Busch, Michael W., additional, Swindle, Timothy D., additional, Brozovic, Marina, additional, Becker, Tracy M., additional, Marshall, Sean E., additional, Virkki, Anne K., additional, Liao, Ying, additional, d'Aubigny, Christian Drouet, additional, Kaplan, Hannah, additional, Naidu, Shantanu P., additional, Jr., Ronald J. Vervack,, additional, Noviello, Jessica, additional, Springmann, Alessondra, additional, Abell, Paul, additional, Li, Jian-Yang, additional, Taylor, Patrick A., additional, Greenhagen, Benjamin, additional, Rivera-Valentín, Edgard G., additional, Chesley, Steven R., additional, Zambrano-Marín, Luisa Fernanda, additional, Lim, Lucy F., additional, Howell, Ellen S., additional, DellaGiustina, Daniella, additional, Fernandez, Yanga R., additional, and Jha, Devanshu, additional

Published

2021

27. Polarimetric Decomposition of Near-Earth Asteroids Using Arecibo Radar Observations

Author

Hickson, Dylan C., primary, Virkki, Anne K., additional, Perillat, Phil, additional, Nolan, Michael C., additional, and Bhiravarasu, Sriram S., additional

Published

2021

28. Modeling Radar Albedos of Laboratory‐Characterized Particles: Application to the Lunar Surface

Author

Virkki, Anne K., primary and Bhiravarasu, Sriram S., additional

Published

2019

29. Shape model and spin-state analysis of PHA contact binary (85990) 1999 JV6 from combined radar and optical observations

Author

Rożek, A., primary, Lowry, S. C., additional, Nolan, M. C., additional, Taylor, P. A., additional, Benner, L. A. M., additional, Fitzsimmons, A., additional, Zegmott, T. J., additional, Weissman, P. R., additional, Green, S. F., additional, Rozitis, B., additional, Snodgrass, C., additional, Smythe, W. D., additional, Hicks, M. D., additional, Howell, E. S., additional, Virkki, A. K., additional, Aponte-Hernandez, B., additional, Rivera-Valentín, E. G., additional, Rodriguez-Ford, L. A., additional, Zambrano-Marin, L. F., additional, Brozović, M., additional, Naidu, S. P., additional, Giorgini, J. D., additional, Snedeker, L. G., additional, Jao, J. S., additional, and Ghigo, F. D., additional

Published

2019

30. Arecibo radar observations of near-Earth asteroid (3200) Phaethon during the 2017 apparition

Author

Taylor, Patrick A., primary, Rivera-Valentín, Edgard G., additional, Benner, Lance A.M., additional, Marshall, Sean E., additional, Virkki, Anne K., additional, Venditti, Flaviane C.F., additional, Zambrano-Marin, Luisa F., additional, Bhiravarasu, Sriram S., additional, Aponte-Hernandez, Betzaida, additional, Rodriguez Sanchez-Vahamonde, Carolina, additional, and Giorgini, Jon D., additional

Published

2019

31. Direct observation of 99942 Apophis with radar.

Author

Herique, A., Plettemeier, D., Kofman, W., Zine, S., Gassot, O., Rogez, Y., Michel, P., Ulamec, S., Biele, J., Ho, T. R., Grundmann, J. T., Perna, D., Goldberg, H., Virkki, A. K., Venditti, F. C. F., Marshall, S. E., and Hickson, D. C.

Subjects

BISTATIC radar, RADAR, CHURYUMOV-Gerasimenko comet, OPTICAL remote sensing

Published

2021

32. BISTATIC ARECIBO PLANETARY RADAR OBSERVATIONS OF 99942 APOPHIS.

Author

Virkki, A. K., Venditti, F. C. F., Hickson, D. C., Perillat, P., Marshall, S. E., Taylor, P. A., and Herique, A.

Subjects

PLANETARY observations, RADAR cross sections, RADAR transmitters, BISTATIC radar, NEAR-earth asteroids, NEAR-Earth objects

Published

2021

33. Radar Reconnaissance of 99942 Apophis.

Author

Brozović, M., Benner, L. A. M., Naidu, S. P., Busch, M. W., Giorgini, J. D., Taylor, P. A., Rivera-Valentin, E. G., Virkki, A. K., Venditti, F. C. F., Marshall, S. E., Nolan, M. C., and Howell, E. S.

Subjects

RADAR, OPTICAL radar, RECONNAISSANCE operations, RADAR targets, METEORS

Published

2021

34. MULTIWAVELENGTH RADAR OBSERVATIONS OF APOPHIS.

Author

Nolan, M. C., Benner, L. A. M., Brozović, M., Busch, M. W., Giorgini, J. D., Hickson, D. C., Howell, E. S., Marshall, S. E., Naidu, S. P., Rivera-Valentín, E. G., Taylor, P. A., Venditti, F. C. F., and Virkki, A. K.

Subjects

RADAR, OBSERVATIONS of the Moon, PLANETARY observations, SOLAR radiation, ASTEROID detection, BISTATIC radar, METEORS

Published

2021

35. Asteroids, Comets, Meteors

Author

Karri Muinonen, Antti Penttilä, Mikael Matias Sebastian Granvik, Virkki, Anne K., Grigori Fedorets, Olli Wilkman, and Tomas Kohout

36. Shape model and spin-state analysis of PHA contact binary (85990) 1999 JV6 from combined radar and optical observations

Author

Rozek, A., Lowry, S. C., Nolan, M. C., Taylor, P. A., Benner, L. A. M., Fitzsimmons, A., Zegmott, T. J., Weissman, P. R., Green, Simon, Rozitis, Benjamin, Snodgrass, Colin, Smythe, W. D., Hicks, M. D., Howell, E. S., Virkki, A. K., Aponte-Hernandez, B., Rivera-Valentin, E. G., Rodriguez-Ford, L. A., Zambrano-Marin, L. F., Brozovic, M., Naidu, S. P., Giorgini, J. D., Snedeker, L. G., Jao, J. S., Ghigo, F. D., Rozek, A., Lowry, S. C., Nolan, M. C., Taylor, P. A., Benner, L. A. M., Fitzsimmons, A., Zegmott, T. J., Weissman, P. R., Green, Simon, Rozitis, Benjamin, Snodgrass, Colin, Smythe, W. D., Hicks, M. D., Howell, E. S., Virkki, A. K., Aponte-Hernandez, B., Rivera-Valentin, E. G., Rodriguez-Ford, L. A., Zambrano-Marin, L. F., Brozovic, M., Naidu, S. P., Giorgini, J. D., Snedeker, L. G., Jao, J. S., and Ghigo, F. D.

Abstract

Context. The potentially hazardous asteroid (85990)1999 JV6 has been a target of previously published thermal-infrared observations and optical photometry. It has been identified as a promising candidate for possible Yarkovsky-O’Keefe-Radzievskii-Paddack (YORP) effect detection. Aims. The YORP effect is a small thermal-radiation torque considered to be a key factor in spin-state evolution of small Solar System bodies. In order to detect YORP on 1999 JV6 we developed a detailed shape model and analysed the spin-state using both optical and radar observations. Methods. For 1999 JV6, we collected optical photometry between 2007 and 2016. Additionally, we obtained radar echo-power spectra and imaging observations with Arecibo and Goldstone planetary radar facilities in 2015, 2016, and 2017. We combined our data with published optical photometry to develop a robust physical model. Results. We determine that the rotation pole resides at negative latitudes in an area with a 5◦ radius close to the south ecliptic pole. The refined sidereal rotation period is 6.536787±0.000007 h. The radar images are best reproduced with a bilobed shape model. Both lobes of 1999 JV6 can be represented as oblate ellipsoids with a smaller, more spherical component resting at the end of a larger, more elongated component. While contact binaries appear to be abundant in the near-Earth population, there are only a few published shape models for asteroids in this particular configuration. By combining the radar-derived shape model with optical light curves we determine a constant-period solution that fits all available data well. Using light-curve data alone we determine an upper limit for YORP of 8.5×10−8 rad day−2. Conclusions. The bifurcated shape of 1999 JV6 might be a result of two ellipsoidal components gently merging with each other, or a deformation of a rubble pile with a weak-tensile-strength core due t