Your search keyword '"Runyon, Kirby"' showing total 157 results

1. Large-scale cryovolcanic resurfacing on Pluto

Author

Singer, Kelsi N., White, Oliver L., Schmitt, Bernard, Rader, Erika L., Protopapa, Silvia, Grundy, William M., Cruikshank, Dale P., Bertrand, Tanguy, Schenk, Paul M., McKinnon, William B., Stern, S. Alan, Dhingra, Rajani D., Runyon, Kirby D., Beyer, Ross A., Bray, Veronica J., Ore, Cristina Dalle, Spencer, John R., Moore, Jeffrey M., Nimmo, Francis, Keane, James T., Young, Leslie A., Olkin, Catherine B., Lauer, Tod R., Weaver, Harold A., and Ennico-Smith, Kimberly

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The New Horizons spacecraft returned images and compositional data showing that terrains on Pluto span a variety of ages, ranging from relatively ancient, heavily cratered areas to very young surfaces with few-to-no impact craters. One of the regions with very few impact craters is dominated by enormous rises with hummocky flanks. Similar features do not exist anywhere else in the imaged solar system. Here we analyze the geomorphology and composition of the features and conclude this region was resurfaced by cryovolcanic processes, of a type and scale so far unique to Pluto. Creation of this terrain requires multiple eruption sites and a large volume of material (>104 km^3) to form what we propose are multiple, several-km-high domes, some of which merge to form more complex planforms. The existence of these massive features suggests Pluto's interior structure and evolution allows for either enhanced retention of heat or more heat overall than was anticipated before New Horizons, which permitted mobilization of water-ice-rich materials late in Pluto's history., Comment: 22 pages, including both main paper and supplement as one pdf

Published

2022

2. Moons Are Planets: Scientific Usefulness Versus Cultural Teleology in the Taxonomy of Planetary Science

Author

Metzger, Philip T., Grundy, William M., Sykes, Mark, Stern, S. Alan, Bell III, James F., Detelich, Charlene E., Runyon, Kirby D., and Summers, Michael

Subjects

Physics - History and Philosophy of Physics, Astrophysics - Earth and Planetary Astrophysics, Physics - Physics Education, Physics - Popular Physics, Physics - Physics and Society

Abstract

We argue that taxonomical concept development is vital for planetary science as in all branches of science, but its importance has been obscured by unique historical developments. The literature shows that the concept of planet developed by scientists during the Copernican Revolution was theory-laden and pragmatic for science. It included both primaries and satellites as planets due to their common intrinsic, geological characteristics. About two centuries later the non-scientific public had just adopted heliocentrism and was motivated to preserve elements of geocentrism including teleology and the assumptions of astrology. This motivated development of a folk concept of planet that contradicted the scientific view. The folk taxonomy was based on what an object orbits, making satellites out to be non-planets and ignoring most asteroids. Astronomers continued to keep primaries and moons classed together as planets and continued teaching that taxonomy until the 1920s. The astronomical community lost interest in planets ca. 1910 to 1955 and during that period complacently accepted the folk concept. Enough time has now elapsed so that modern astronomers forgot this history and rewrote it to claim that the folk taxonomy is the one that was created by the Copernican scientists. Starting ca. 1960 when spacecraft missions were developed to send back detailed new data, there was an explosion of publishing about planets including the satellites, leading to revival of the Copernican planet concept. We present evidence that taxonomical alignment with geological complexity is the most useful scientific taxonomy for planets. It is this complexity of both primary and secondary planets that is a key part of the chain of origins for life in the cosmos., Comment: 68 pages, 16 figures. For supplemental data files, see https://www.philipmetzger.com/moons_are_planets/

Published

2021

3. Large-scale cryovolcanic resurfacing on Pluto

Author

Singer, Kelsi N, White, Oliver L, Schmitt, Bernard, Rader, Erika L, Protopapa, Silvia, Grundy, William M, Cruikshank, Dale P, Bertrand, Tanguy, Schenk, Paul M, McKinnon, William B, Stern, S Alan, Dhingra, Rajani D, Runyon, Kirby D, Beyer, Ross A, Bray, Veronica J, Ore, Cristina Dalle, Spencer, John R, Moore, Jeffrey M, Nimmo, Francis, Keane, James T, Young, Leslie A, Olkin, Catherine B, Lauer, Tod R, Weaver, Harold A, and Ennico-Smith, Kimberly

Subjects

Earth Sciences, Physical Sciences, Space Sciences, Geology

Abstract

The New Horizons spacecraft returned images and compositional data showing that terrains on Pluto span a variety of ages, ranging from relatively ancient, heavily cratered areas to very young surfaces with few-to-no impact craters. One of the regions with very few impact craters is dominated by enormous rises with hummocky flanks. Similar features do not exist anywhere else in the imaged solar system. Here we analyze the geomorphology and composition of the features and conclude this region was resurfaced by cryovolcanic processes, of a type and scale so far unique to Pluto. Creation of this terrain requires multiple eruption sites and a large volume of material (>104 km3) to form what we propose are multiple, several-km-high domes, some of which merge to form more complex planforms. The existence of these massive features suggests Pluto's interior structure and evolution allows for either enhanced retention of heat or more heat overall than was anticipated before New Horizons, which permitted mobilization of water-ice-rich materials late in Pluto's history.

Published

2022

4. Morphological Comparison of Blocks in Chaos Terrains on Pluto, Europa, and Mars

Author

Skjetne, Helle L., Singer, Kelsi N., Hynek, Brian M., Knight, Katie I., Schenk, Paul M., Olkin, Cathy B., White, Oliver L., Bertrand, Tanguy, Runyon, Kirby D., McKinnon, William B., Moore, Jeffrey M., Stern, S. Alan, Weaver, Harold A., Young, Leslie A., and Ennico, Kim

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Geophysics

Abstract

Chaos terrains are characterized by disruption of preexisting surfaces into irregularly arranged mountain blocks with a chaotic appearance. Several models for chaos formation have been proposed, but the formation and evolution of this enigmatic terrain type has not yet been fully constrained. We provide extensive mapping of the individual blocks that make up different chaos landscapes, and present a morphological comparison of chaotic terrains found on Pluto, Jupiter's moon Europa, and Mars, using measurements of diameter, height, and axial ratio of chaotic mountain blocks. Additionally, we compare mountain blocks in chaotic terrain and fretted terrain on Mars. We find a positive linear relationship between the size and height of chaos blocks on Pluto and Mars, whereas blocks on Europa exhibit a flat trend as block height does not generally increase with increasing block size. Block heights on Pluto are used to estimate the block root depths if they were floating icebergs. Block heights on Europa are used to infer the total thickness of the icy layer from which the blocks formed. Finally, block heights on Mars are compared to potential layer thicknesses of near-surface material. We propose that the heights of chaotic mountain blocks on Pluto, Europa, and Mars can be used to infer information about crustal lithology and surface layer thickness., Comment: 45 pages, 3 tables, 9 figures, 5 appendices

Published

2021

5. Human Assisted Science at Venus: Venus Exploration in the New Human Spaceflight Age

Author

Izenberg, Noam R., McNutt Jr., Ralph L., Runyon, Kirby D., Byrne, Paul K., and Macdonald, Alexander

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Popular Physics

Abstract

Some human mission trajectories to Mars include flybys of Venus. These flybys provide opportunities to practice deep space human operations, and offer numerous safe-return-to-Earth options, before committing to longer and lower-cadence Mars-only flights. Venus flybys, as part of dedicated missions to Mars, also enable human-in-the-loop scientific study of the second planet. The time to begin coordinating such Earth-to-Mars-via-Venus missions is now, Comment: A White Paper for the Planetary Science and Astrobiology Decadal Survey 2023-2032. 7 pages +cover page, 2 figures +cover image

Published

2020

6. Sediment-moving winds and abrasion on Titan: Implications for yardangs

Author

MacKenzie, Shannon M., Runyon, Kirby D., Yu, Xinting, Kok, Jasper F., Newman, Claire, Lorenz, Ralph D., and Comola, Francesco

Published

2023

7. Great Expectations: Plans and Predictions for New Horizons Encounter with Kuiper Belt Object 2014 MU69 ('Ultima Thule')

Author

Moore, Jeffrey M., McKinnon, William B., Cruikshank, Dale P., Gladstone, G. Randall, Spencer, John R., Stern, S. Alan, Weaver, Harold A., Singer, Kelsi N., Showalter, Mark R., Grundy, William M., Beyer, Ross A., White, Oliver L., Binzel, Richard P., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Howett, Carly, Olkin, Cathy B., Parker, Alex H., Porter, Simon B., Schenk, Paul M., Throop, Henry B., Verbiscer, Anne J., Young, Leslie A., Benecchi, Susan D., Bray, Veronica J., Chavez, Carrie. L., Dhingra, Rajani D., Howard, Alan D., Lauer, Tod R., Lisse, C. M., Robbins, Stuart J., Runyon, Kirby D., and Umurhan, Orkan M.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The New Horizons encounter with the cold classical Kuiper Belt object (KBO) 2014 MU69 (informally named 'Ultima Thule,' hereafter Ultima) on 1 January 2019 will be the first time a spacecraft has ever closely observed one of the free-orbiting small denizens of the Kuiper Belt. Related to but not thought to have formed in the same region of the Solar System as the comets that been explored so far, it will also be the largest, most distant, and most primitive body yet visited by spacecraft. In this letter we begin with a brief overview of cold classical KBOs, of which Ultima is a prime example. We give a short preview of our encounter plans. We note what is currently known about Ultima from earth-based observations. We then review our expectations and capabilities to evaluate Ultima's composition, surface geology, structure, near space environment, small moons, rings, and the search for activity.

Published

2018

8. The Reclassification of Asteroids from Planets to Non-Planets

Author

Metzger, Philip T., Sykes, Mark V., Stern, Alan, and Runyon, Kirby

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - History and Philosophy of Physics, Physics - Popular Physics

Abstract

It is often claimed that asteroids' sharing of orbits is the reason they were re-classified from planets to non-planets. A critical review of the literature from the 19th Century to the present shows this is factually incorrect. The literature shows the term asteroid was broadly recognized as a subset of planet for 150 years. On-going discovery of asteroids resulted in a de facto stretching of the concept of planet to include the ever-smaller bodies. Scientists found utility in this taxonomic identification as it provided categories needed to argue for the leading hypothesis of planet formation, Laplace's nebular hypothesis. In the 1950s, developments in planet formation theory found it no longer useful to maintain taxonomic identification between asteroids and planets, Ceres being the primary exception. At approximately the same time, there was a flood of publications on the geophysical nature of asteroids showing them to be geophysically different than the large planets. This is when the terminology in asteroid publications calling them planets abruptly plunged from a high level of usage where it had hovered during the period 1801 - 1957 to a low level that held constant thereafter. This marks the point where the community effectively formed consensus that asteroids should be taxonomically distinct from planets. The evidence demonstrates this consensus formed on the basis of geophysical differences between asteroids and planets, not the sharing of orbits. We suggest attempts to build consensus around planetary taxonomy not rely on the non-scientific process of voting, but rather through precedent set in scientific literature and discourse, by which perspectives evolve with additional observations and information, just as they did in the case of asteroids., Comment: 31 pages, 5 figures

Published

2018

9. Multi-year measurements of ripple and dune migration on Mars: Implications for the wind regime and sand transport

Author

Roback, Kevin P., Runyon, Kirby, Newman, Claire, and Avouac, Jean-Philippe

Published

2022

10. Moons are planets: Scientific usefulness versus cultural teleology in the taxonomy of planetary science

Author

Metzger, Philip T., Grundy, W.M., Sykes, Mark V., Stern, Alan, Bell, James F., III, Detelich, Charlene E., Runyon, Kirby, and Summers, Michael

Published

2022

11. The Geology of Pluto and Charon Through the Eyes of New Horizons

Author

Moore, Jeffrey M., McKinnon, William B., Spencer, John R., Howard, Alan D., Schenk, Paul M., Beyer, Ross A., Nimmo, Francis, Singer, Kelsi N., Umurhan, Orkan M., White, Oliver L., Stern, S. Alan, Ennico, Kimberly, Olkin, Cathy B., Weaver, Harold A., Young, Leslie A., Binzel, Richard P., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Cruikshank, Dale P., Grundy, Will M., Linscott, Ivan R., Reitsema, Harold J., Reuter, Dennis C., Showalter, Mark R., Bray, Veronica J., Chavez, Carrie L., Howett, Carly J. A., Lauer, Tod R., Lisse, Carey M., Parker, Alex Harrison, Porter, S. B., Robbins, Simon J., Runyon, Kirby, Stryk, Ted, Throop, Henry B., Tsang, Constantine C. C., Verbiscer, Anne J., Zangari, Amanda M., Chaikin, Andrew L., and Wilhelms, Don E.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

NASA's New Horizons spacecraft has revealed the complex geology of Pluto and Charon. Pluto's encounter hemisphere shows ongoing surface geological activity centered on a vast basin containing a thick layer of volatile ices that appears to be involved in convection and advection, with a crater retention age no greater than $\approx$10 Ma. Surrounding terrains show active glacial flow, apparent transport and rotation of large buoyant water-ice crustal blocks, and pitting, likely by sublimation erosion and/or collapse. More enigmatic features include tall mounds with central depressions that are conceivably cryovolcanic, and ridges with complex bladed textures. Pluto also has ancient cratered terrains up to ~4 Ga old that are extensionally fractured and extensively mantled and perhaps eroded by glacial or other processes. Charon does not appear to be currently active, but experienced major extensional tectonism and resurfacing (probably cryovolcanic) nearly 4 billion years ago. Impact crater populations on Pluto and Charon are not consistent with the steepest proposed impactor size-frequency distributions proposed for the Kuiper belt.

Published

2016

12. Venus Exploration in the New Human Spaceflight Age

Author

Izenberg, Noam R., McNutt, Ralph L., Jr., Runyon, Kirby D., Byrne, Paul K., and MacDonald, Alexander

Published

2021

13. Depths of Pluto's and Charon's craters, and their simple-to-complex transition

Author

Robbins, Stuart J., Schenk, Paul M., Riggs, Jamie D., Parker, Alex H., Bray, Veronica J., Beddingfield, Chloe B., Beyer, Ross A., Verbiscer, Anne J., Binzel, Richard, and Runyon, Kirby D.

Published

2021

14. Cryovolcanic flooding in Viking Terra on Pluto

Author

Cruikshank, Dale P., Dalle Ore, Cristina M., Scipioni, Francesca, Beyer, Ross A., White, Oliver L., Moore, Jeffrey M., Grundy, William M., Schmitt, Bernard, Runyon, Kirby D., Keane, James T., Robbins, Stuart J., Stern, S. Alan, Bertrand, Tanguy, Beddingfield, Chloe B., Olkin, Catherine B., Young, Leslie A., Weaver, Harold A., and Ennico, Kimberly

Published

2021

15. Reconstruction of the sand transport pathways and provenance in Moreux crater, Mars

Author

Cardinale, Marco, Pozzobon, Riccardo, Tangari, Anna Chiara, Runyon, Kirby, Di Primio, Maristella, and Marinangeli, Lucia

Published

2020

16. Landslides on Charon

Author

Beddingfield, Chloe B., Beyer, Ross A., Singer, Kelsi N., McKinnon, William B., Runyon, Kirby, Grundy, Will, Stern, S. Alan, Bray, Veronica, Dhingra, Rajani, Moore, Jeffrey M., Ennico, K., Olkin, C.B., Schenk, Paul, Spencer, John R., Weaver, H.A., and Young, L.A.

Published

2020

17. Recent cryovolcanism in Virgil Fossae on Pluto

Author

Cruikshank, Dale P., Umurhan, Orkan M., Beyer, Ross A., Schmitt, Bernard, Keane, James T., Runyon, Kirby D., Atri, Dimitra, White, Oliver L., Matsuyama, Isamu, Moore, Jeffrey M., McKinnon, William B., Sandford, Scott A., Singer, Kelsi N., Grundy, William M., Dalle Ore, Cristina M., Cook, Jason C., Bertrand, Tanguy, Stern, S. Alan, Olkin, Catherine B., Weaver, Harold A., Young, Leslie A., Spencer, John R., Lisse, Carey M., Binzel, Richard P., Earle, Alissa M., Robbins, Stuart J., Gladstone, G. Randall, Cartwright, Richard J., and Ennico, Kimberly

Published

2019

18. Dunes on Pluto

Author

The New Horizons Geology, Geophysics and Imaging Science Theme Team, Telfer, Matt W., Parteli, Eric J. R., Radebaugh, Jani, Beyer, Ross A., Bertrand, Tanguy, Forget, François, Nimmo, Francis, Grundy, Will M., Moore, Jeffrey M., Stern, S. Alan, Spencer, John, Lauer, Tod R., Earle, Alissa M., Binzel, Richard P., A.Weaver, Hal, Olkin, Cathy B., Young, Leslie A., Ennico, Kimberly, and Runyon, Kirby

Published

2018

19. Preliminary laboratory investigations of ejecta emplacement dynamics and morphology with planetary applications

Author

Runyon, Kirby D. and Barnouin, Olivier S.

Published

2018

20. Photogeologic Map of the Perseverance Rover Field Site in Jezero Crater Constructed by the Mars 2020 Science Team

Author

Stack, Kathryn M., Williams, Nathan R., Calef, III, Fred, Sun, Vivian Z., Williford, Kenneth H., Farley, Kenneth A., Eide, Sigurd, Flannery, David, Hughes, Cory, Jacob, Samantha R., Kah, Linda C., Meyen, Forrest, Molina, Antonio, Nataf, Cathy Quantin, Rice, Melissa, Russell, Patrick, Scheller, Eva, Seeger, Christina H., Abbey, William J., Adler, Jacob B., Amundsen, Hans, Anderson, Ryan B., Angel, Stanley M., Arana, Gorka, Atkins, James, Barrington, Megan, Berger, Tor, Borden, Rose, Boring, Beau, Brown, Adrian, Carrier, Brandi L., Conrad, Pamela, Dypvik, Henning, Fagents, Sarah A., Gallegos, Zachary E., Garczynski, Brad, Golder, Keenan, Gomez, Felipe, Goreva, Yulia, Gupta, Sanjeev, Hamran, Svein-Erik, Hicks, Taryn, Hinterman, Eric D., Horgan, Briony N., Hurowitz, Joel, Johnson, Jeffrey R., Lasue, Jeremie, Kronyak, Rachel E., Liu, Yang, Madariaga, Juan Manuel, Mangold, Nicolas, McClean, John, Miklusicak, Noah, Nunes, Daniel, Rojas, Corrine, Runyon, Kirby, Schmitz, Nicole, Scudder, Noel, Shaver, Emily, SooHoo, Jason, Spaulding, Russell, Stanish, Evan, Tamppari, Leslie K., Tice, Michael M., Turenne, Nathalie, Willis, Peter A., and Aileen Yingst, R.

Published

2020

21. Martian sand sheet characterization and implications for formation: A case study

Author

Runyon, Kirby D., Bridges, Nathan T., and Newman, Claire E.

Published

2017

22. Pushing the Frontier of Solar & Space Physics: Exploration of the Heliosphere and the Very Local Interstellar Medium by an Interstellar Probe

Author

Brandt, Pontus, primary, Alterman, Benjamin, additional, Alvarez, Erika, additional, Baker, Daniel, additional, Bale, Stuart, additional, Baliukin, Igor, additional, Barabash, Stas, additional, Beichman, Charles, additional, Bergman, Jan, additional, Bertaux, Jean-Loup, additional, Bladek, Piotr, additional, Blanc, Michel, additional, Christian, Eric, additional, Clarke, John, additional, Cocoros, Alice, additional, Cooper, John, additional, Decker, Robert, additional, DeMajistre, Robert, additional, Desai, Mihir, additional, Dialynas, Kostas, additional, Dodd, Suzanne, additional, Eriksson, Stefan, additional, Fedorov, Andrei, additional, Fields, Brian, additional, Fisk, Lennard, additional, Fountain, Glen, additional, Friedman, Louis, additional, Frisch, Priscilla, additional, Fujimoto, Masaki, additional, Funsten, Herbert, additional, Galli, Andre, additional, Gavilian, Lisseth, additional, Gkioulidou, Matina, additional, Gladstone, Randy, additional, Gloeckler, George, additional, Gruntman, Mike, additional, Gurvits, Leonid, additional, Harman, Sonny, additional, Hill, Matthew, additional, Ho, George, additional, Holler, Bryan, additional, Horanyi, Mihaly, additional, Horbury, Timothy, additional, Hunziker, Silvan, additional, Iess, Luciano, additional, Katushkina, Olga, additional, Kempf, Sascha, additional, Kha, Kathy, additional, Kinnison, James, additional, Kornbleuth, Marc, additional, Korreck, Kelly, additional, Krimigis, Tom, additional, Kucharek, Harald, additional, Kurth, William, additional, Lallement, Rosine, additional, Lavraud, Benoit, additional, Liewer, Paulett, additional, Linsky, Jeffrey, additional, Lisse, Casey, additional, Livi, Stefano, additional, Magnes, Werner, additional, Mandt, Kathleen, additional, Mayyasi, Majd, additional, McNutt, Ralph, additional, Mewaldt, Richard, additional, Miller, Jesse, additional, Mitchell, Donald, additional, Moebius, Eberhard, additional, Mostafavi, Parisa, additional, Nicolaou, Georgios, additional, Nikoukar, Romina, additional, Opher, Merav, additional, Owino, Stephen, additional, Park, Jeewoo, additional, Paschalidis, Nikolaos, additional, Paul, Michael, additional, Paxton, Larry, additional, Plaschke, Ferdinand, additional, Plumaris, Michael, additional, Pogorelov, Nikolai, additional, Poppe, Andrew, additional, Provornikova, Elena, additional, Ratkiewicz, Romana, additional, Redfield, Seth, additional, Reisenfeld, Daniel, additional, Retherford, Kurt, additional, Richardson, John, additional, Roelof, Edmond, additional, Runyon, Kirby, additional, Rymer, Abigail, additional, Santos-Costa, Daniel, additional, Schwadron, Nathan, additional, Sigurdsson, Steinn, additional, Slavin, Jonathan, additional, Smith, Todd, additional, Sokol, Justyna, additional, Sorriso-Valvo, Luca, additional, Spilker, Linda, additional, Spitzer, Sarah, additional, Stapelfeldt, Karl, additional, Sterken, Veerle, additional, Stern, Alan, additional, Stough, Robert, additional, Swaczyna, Pawel, additional, Szabo, Adam, additional, Szalay, Jamey, additional, Turner, Drew, additional, Vertesi, Janet, additional, Wahlund, Jan-Erik, additional, Wang, Chi, additional, Westlake, Joseph, additional, Wicks, Robert, additional, Wimmer-Schweingruber, Robert, additional, Wood, Brian, additional, Wurz, Peter, additional, Zarka, Philippe, additional, Zemcov, Michael, additional, Zirnstein, Eric, additional, and Zong, Qiugang, additional

Published

2023

23. Advancing Space Science Requires NASA Support for Coordination Between the Science Mission Directorate Communities

Author

Mandt, Kathleen, primary, Rymer, Abigail, additional, Kalirai, Jason, additional, Allen, Robert, additional, Cocoros, Alice, additional, Stevenson, Kevin, additional, Hurley, Dana, additional, Lisse, Carey, additional, Runyon, Kirby, additional, Dalba, Paul, additional, Domagal-Goldman, Shawn, additional, Kane, Stephen R., additional, Brandt, Pontus, additional, Provornikova, Elena, additional, Meadows, Victoria, additional, Vervack, Ronald, additional, Roberge, Aki, additional, Dong, Chuanfei, additional, Arney, Giada, additional, Bodewits, Dennis, additional, Simon, Amy, additional, Rivera-Valentine, Edgard, additional, Soderland, Krista, additional, Diniega, Serina, additional, Bayless, Amanda, additional, Richey, Christina, additional, Becker, Tracy, additional, Schmidt, Britney, additional, Val-Borro, Miguel de, additional, Milam, Stefanie, additional, Quick, Lynnae, additional, Turner, Neal, additional, Angerhausen, Daniel, additional, Dyar, Darby, additional, Samara, Marilia, additional, Hendrix, Amanda, additional, Soto, Alejandro, additional, Miller, Kelly, additional, Mahaffy, Paul, additional, Quintana, Elisa, additional, Bergin, Edwin A., additional, Vidaurri, Monica R., additional, Bryne, Paul, additional, Danchi, William C., additional, Mayorga, Laura, additional, Marley, Mark S., additional, Barnes, Rory, additional, Genio, Anthony D. Del, additional, Plavchan, Peter, additional, Turnbull, Margaret C., additional, Gelino, Dawn M., additional, Wright, Jason T., additional, Meyer, Michael R., additional, Pepper, Joshua, additional, Dragomir, Diana, additional, Garcia-Sage, Katherine, additional, Solmaz, Arif, additional, Heavens, Nicholas, additional, Beatty, Thomas, additional, Redfield, Seth, additional, Melis, Carl, additional, Stapelfeldt, Karl, additional, Drake, Jeremy, additional, Lovato, Kylie, additional, Hasegawa, Yasuhiro, additional, Smith, Erin C., additional, Curry, Shannon, additional, Jenkins, Jon M., additional, Jackson, Brian, additional, Cartwright, Richard, additional, Cohen, Ian J., additional, Retherford, Kurt, additional, Pinella-Alonso, Noemi, additional, Paganelli, Flora, additional, Accomazzi, Alberto, additional, Fortney, Jonathan, additional, Nikoukar, Romina, additional, and Chen, Thomas Y., additional

Published

2023

24. Interstellar Probe at the Intersection of Heliophysics & Planetary Science: Probing Endo- & Exo-Heliospheric Environments with Trans-Neptunian Objects

Author

Holler, Bryan, primary, Runyon, Kirby, additional, Ahrens, Caitlin, additional, Annex, Andrew, additional, Bannister, Michele, additional, Beddingfield, Chloe, additional, Benecchi, Susan, additional, Brandt, Pontus, additional, Britt, Daniel, additional, Cahill, Joshua, additional, Cartwright, Richard, additional, Chen, Thomas, additional, Cohen, Ian, additional, Cooper, John, additional, Gladstone, Randy, additional, Harman, Chester, additional, Izenberg, Noam, additional, Kite, Edwin, additional, Keane, James, additional, Kollmann, Peter, additional, Lisse, Carey, additional, Pinilla-Alonso, Noemí, additional, Provornikova, Elena, additional, Quirico, Eric, additional, Rymer, Abigail, additional, Scipioni, Francesca, additional, Singer, Kelsi, additional, Spitzer, Sarah, additional, Stern, Alan, additional, and Stryk, Ted, additional

Published

2023

25. Craters of the Pluto-Charon system

Author

Robbins, Stuart J., Singer, Kelsi N., Bray, Veronica J., Schenk, Paul, Lauer, Tod R., Weaver, Harold A., Runyon, Kirby, McKinnon, William B., Beyer, Ross A., Porter, Simon, White, Oliver L., Hofgartner, Jason D., Zangari, Amanda M., Moore, Jeffrey M., Young, Leslie A., Spencer, John R., Binzel, Richard P., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Grundy, William M., Linscott, Ivan R., Reitsema, Harold J., Reuter, Dennis C., Showalter, Mark R., Tyler, G. Len, Olkin, Catherine B., Ennico, Kimberly S., and Stern, S. Alan

Published

2017

26. Recurring Slope Lineae

Author

Runyon, Kirby, Ojha, Lujendra, Hargitai, Henrik, editor, and Kereszturi, Ákos, editor

Published

2015

27. Water Track (Antarctica)

Author

Runyon, Kirby, Hargitai, Henrik, editor, and Kereszturi, Ákos, editor

Published

2015

28. Slope Lineae

Author

Runyon, Kirby, Ojha, Lujendra, Hargitai, Henrik, Hargitai, Henrik, editor, and Kereszturi, Ákos, editor

Published

2015

29. Patterns in Mobility and Modification of Middle and High-Latitude Southern Hemisphere Dunes on Mars

Author

Banks, Maria E, Fenton, Lori K, Bridges, Nathan T, Geissler, Paul E, Chojnacki, Matthew, Runyon, Kirby D, Silvestro, Simone, and Zimbelman, James R

Subjects

Lunar And Planetary Science And Exploration

Abstract

Change detection analyses of aeolian bedforms (dunes and ripples), using multitemporal imagesacquired by the Mars Reconnaissance Orbiter High Resolution Imaging Science Experiment (HiRISE), canreveal migration of bedforms on Mars. Here we investigated bedform mobility (evidence of wind-drivenmigration or activity), from analysis of HiRISE temporal image pairs, and dune field modification (i.e., apparentpresence/lack of changes or degradation due to nonaeolian processes) through use of a dune stability indexor SI (1–6; higher numbers indicating increasing evidence of stability/modification). Combining mobility dataand SI for 70 dune fields south of 40°S latitude, we observed a clear trend of decreasing bedform mobility withincreasing SI and latitude. Both dunes and ripples were more commonly active at lower latitudes, althoughsome high-latitude ripples are migrating. Most dune fields with lower SIs (3) were found to be active whilethose with higher SIs were primarily found to be inactive. A shift in prevalence of active to apparently inactivebedforms and to dune fields with SI 2 occurs at ~60°S latitude, coincident with the edge of highconcentrations of H2O-equivalent hydrogen observed by the Mars Odyssey Neutron Spectrometer. This result isconsistent with previous studies suggesting that stabilizing agents, such as ground ice, likely stabilize bedformsand limit sediment availability. Observations of active dune fields with morphologies indicative of stability(i.e., migrating ripples in SI = 3 dune fields) may have implications for episodic phases of reworking or dunebuilding, and possibly geologically recent activation or stabilization corresponding to shifts in climate

Published

2018

30. Prospecting for Lunar Polar Ice from Very Low Lunar Orbit: How Low Can You Go?

Author

Shannon, Jackson, primary, Hibbitts, Charles, additional, Runyon, Kirby, additional, and Nord, Michael E., additional

Published

2022

31. High-priority lunar landing sites for in situ and sample return studies of polar volatiles

Author

Lemelin, Myriam, Blair, David M., Roberts, Carolyn E., Runyon, Kirby D., Nowka, Daniela, and Kring, David A.

Published

2014

32. Meeting With the Goddess: Notes from the First Symposium on Venus Science Enabled by Human Proximity

Author

Izenberg, Noam, Lefland, Mallory, MacDonald, Alexander, Beauchamp, Patricia, Chai, Patrick, Cummings, Nick, Esty, Clark, Daniels, Matt, Duggan, Matt, Goods, Dan, Grinspoon, David, Landers, Jamie, Runyon, Kirby, Shelhamer, Mark, Tymofyeyeva, Ekaterina, Wallace, Mark, Worden, Pete, Yant, Marcella, Izenberg, Noam, Lefland, Mallory, MacDonald, Alexander, Beauchamp, Patricia, Chai, Patrick, Cummings, Nick, Esty, Clark, Daniels, Matt, Duggan, Matt, Goods, Dan, Grinspoon, David, Landers, Jamie, Runyon, Kirby, Shelhamer, Mark, Tymofyeyeva, Ekaterina, Wallace, Mark, Worden, Pete, and Yant, Marcella

Abstract

In July of 2022, the Keck Institute for Space Studies (KISS) hosted a symposium entitled "Science Enabled by Human Proximity to Venus." Convened to explore the potential science that could be enabled by human mission fly-bys of Venus while en route to Mars, the symposium conversation expanded to encompass the policy and social rationales for a dedicated human mission to Venus, as well as a new concept for a potential human mission to Venus—The Venus Back-Flip. This symposium summary, compiled by contributions from symposium participants listed at the beginning of this report, is the start of a broader discussion that is likely to become more and more relevant in the coming years as the multiple human space exploration capabilities under development provide potential opportunities to execute a human mission to Venus—whether en route to Mars or as a dedicated mission. This summary will outline some of the relevant options for Venus human fly-by and orbital missions, some of the new or enhanced science investigations that could be achieved in tandem with human fly-by or orbital missions, why integrating Venus into the overall Moon-to-Mars strategy may be valuable, how social and cultural activities might advance human missions to Venus, and why Venus may deserve its own journey of exploration independent of other destinations. This report is a summary of the discussions, observations, and ideas that were generated at the symposium. The summary is written primarily for three types of audiences: human spaceflight mission and campaign planners, Venus scientists and technical innovators, and individuals interested in the social aspects of organizing to promote the human exploration of Venus. The symposium revealed that Venus is a desirable human spaceflight destination in its own right. The compelling narrative of exploration combines planetary science at Venus, the search for life in its clouds, and an encounter with our sister planet that may shed light on our future cli

Published

2022

33. Space radiation environment considerations for the Interstellar Probe mission

Author

Likar, Justin, primary, Porter, Jamie, additional, Donegan, Michelle, additional, Kinnison, Jim, additional, Brandt, Pontus, additional, McNutt, Ralph, additional, Paul, Michael, additional, Runyon, Kirby, additional, Haapala, Amanda, additional, Cocoros, Alice, additional, and Siddique, Fazle, additional

Published

2022

34. Wet Patch (Antarctica)

Author

Runyon, Kirby, Hargitai, Henrik, editor, and Kereszturi, Ákos, editor

Published

2015

35. Identifying Impact Melt from the Smythii Basin: Toward an Improved Chronology for Lunar Basin Formation

Author

Runyon, Kirby D., primary, Nelson, Lyle, additional, and Moriarty III, Daniel P., additional

Published

2022

36. PLANETARY SCIENCE: The geology of Pluto and Charon through the eyes of New Horizons

Author

Moore, Jeffrey M., McKinnon, William B., Spencer, John R., Howard, Alan D., Schenk, Paul M., Beyer, Ross A., Nimmo, Francis, Singer, Kelsi N., Umurhan, Orkan M., White, Oliver L., Stern, Alan S., Ennico, Kimberly, Olkin, Cathy B., Weaver, Harold A., Young, Leslie A., Binzel, Richard P., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Cruikshank, Dale P., Grundy, Will M., Linscott, Ivan R., Reitsema, Harold J., Reuter, Dennis C., Showalter, Mark R., Bray, Veronica J., Chavez, Carrie L., Howett, Carly J.A., Lauer, Tod R., Lisse, Carey M., Parker, Alex Harrison, Porter, S. B., Robbins, Stuart J., Runyon, Kirby, Stryk, Ted, Throop, Henry B., Tsang, Constantine C.C., Verbiscer, Anne J., Zangari, Amanda M., Chaikin, Andrew L., Wilhelms, Don E., and Science Team, New Horizons

Published

2016

37. Craters of the Pluto-Charon System

Author

Robbins, Stuart J, Singer, Kelsi N, Bray, Veronica J, Schenk, Paul, Lauer, Todd R, Weaver, Harold A, Runyon, Kirby, Mckinnon, William B, Beyer, Ross A, Porter, Simon, White, Oliver L, Hofgartner, Jason D, Zangari, Amanda M, Moore, Jeffrey M, Young, Leslie A, Spencer, John R, Binzel, Richard P, Buie, Marc W, Buratti, Bonnie J, Cheng, Andrew F, Grundy, William M, Linscott, Ivan R, Reitsema, Harold J, Reuter, Dennis C, Showalter, Mark R, Tyler, G. Len, Olkin, Catherine B, Ennico, Kimberly S, and Stern, S. Alan

Subjects

Space Sciences (General)

Abstract

NASA's New Horizons flyby mission of the Pluto-Charon binary system and its four moons provided humanity with its first spacecraft-based look at a large Kuiper Belt Object beyond Triton. Excluding this system, multiple Kuiper Belt Objects (KBOs) have been observed for only 20 years from Earth, and the KBO size distribution is unconstrained except among the largest objects. Because small KBOs will remain beyond the capabilities of ground-based observatories for the foreseeable future, one of the best ways to constrain the small KBO population is to examine the craters they have made on the Pluto-Charon system. The first step to understanding the crater population is to map it. In this work, we describe the steps undertaken to produce a robust crater database of impact features on Pluto, Charon, and their two largest moons, Nix and Hydra. These include an examination of different types of images and image processing, and we present an analysis of variability among the crater mapping team, where crater diameters were found to average +/-10% uncertainty across all sizes measured (approx.0.5-300 km). We also present a few basic analyses of the crater databases, finding that Pluto's craters' differential size-frequency distribution across the encounter hemisphere has a power-law slope of approximately -3.1 +/- 0.1 over diameters D approx. = 15-200 km, and Charon's has a slope of -3.0 +/- 0.2 over diameters D approx. = 10-120 km; it is significantly shallower on both bodies at smaller diameters. We also better quantify evidence of resurfacing evidenced by Pluto's craters in contrast with Charon's. With this work, we are also releasing our database of potential and probable impact craters: 5287 on Pluto, 2287 on Charon, 35 on Nix, and 6 on Hydra.

Published

2016

38. Lunar Surface Innovation Consortium ISRU Supply and Demand Workshop, Sept. 17 2020

Author

Nord, Michael E., primary, Runyon, Kirby, additional, and Hibbitts, Karl, additional

Published

2021

39. The Dark Side of Pluto

Author

Lauer, Tod R., primary, Spencer, John R., additional, Bertrand, Tanguy, additional, Beyer, Ross A., additional, Runyon, Kirby D,, additional, L White, Oliver, additional, Young, Leslie A., additional, Ennico, Kimberly, additional, McKinnon, William B., additional, Moore, Jeffrey M., additional, Olkin, Catherine B., additional, Stern, S. Alan, additional, and Weaver, Harold A., additional

Published

2021

40. Neptune Odyssey: A Flagship Concept for the Exploration of the Neptune–Triton System

Author

Rymer, Abigail M., primary, Runyon, Kirby D., additional, Clyde, Brenda, additional, Núñez, Jorge I., additional, Nikoukar, Romina, additional, Soderlund, Krista M., additional, Sayanagi, Kunio, additional, Hofstadter, Mark, additional, Quick, Lynnae C., additional, Stern, S. Alan, additional, Becker, Tracy, additional, Hedman, Matthew, additional, Cohen, Ian, additional, Crary, Frank, additional, Fortney, Jonathan J., additional, Vertesi, Janet, additional, Hansen, Candy, additional, de Pater, Imke, additional, Paty, Carol, additional, Spilker, Thomas, additional, Stallard, Tom, additional, Hospodarsky, George B., additional, Smith, H. Todd, additional, Wakeford, Hannah, additional, Moran, Sarah E., additional, Annex, Andrew, additional, Schenk, Paul, additional, Ozimek, Martin, additional, Arrieta, Juan, additional, McNutt, Ralph L., additional, Masters, Adam, additional, Simon, Amy A., additional, Ensor, Susan, additional, Apland, Clint T., additional, Bruzzi, Jonathan, additional, Patthoff, D. Alex, additional, Scott, Christopher, additional, Campo, Christian, additional, Krupiarz, Christopher, additional, Cochrane, Corey J., additional, Gantz, Curt, additional, Rodriguez, Dan, additional, Gallagher, Dan, additional, Hurley, Dana, additional, Crowley, Doug, additional, Abel, Elizabeth, additional, Provornikova, Elena, additional, Turtle, Elizabeth P., additional, Clark, George, additional, Wilkes, Jacob, additional, Hunt, Jack, additional, Roberts, James H., additional, Rehm, Jeremy, additional, Murray, Kelvin, additional, Wolfarth, Larry, additional, Fletcher, Leigh N., additional, Spilker, Linda, additional, Martin, Emily S., additional, Parisi, Marzia, additional, Norkus, Mike, additional, Izenberg, Noam, additional, Stough, Robert, additional, Vervack, Ron J., additional, Mandt, Kathleen, additional, Stevenson, Kevin B., additional, Kijewski, Seth, additional, Cheng, Weilun, additional, Feldman, Jay D., additional, Allen, Gary, additional, Prabhu, Dinesh, additional, Dutta, Soumya, additional, Young, Cindy, additional, and Williams, Joseph, additional

Published

2021

41. Triton: Topography and Geology of a Probable Ocean World with Comparison to Pluto and Charon

Author

Schenk, Paul, primary, Beddingfield, Chloe, additional, Bertrand, Tanguy, additional, Bierson, Carver, additional, Beyer, Ross, additional, Bray, Veronica, additional, Cruikshank, Dale, additional, Grundy, William, additional, Hansen, Candice, additional, Hofgartner, Jason, additional, Martin, Emily, additional, McKinnon, William, additional, Moore, Jeffrey, additional, Robbins, Stuart, additional, Runyon, Kirby, additional, Singer, Kelsi, additional, Spencer, John, additional, Stern, S., additional, and Stryk, Ted, additional

Published

2021

42. Wet Patch (Antarctica)

Author

Runyon, Kirby, primary

Published

2014

43. Recurring Slope Lineae

Author

Runyon, Kirby, primary and Ojha, Lujendra, additional

Published

2014

44. Water Track (Antarctica)

Author

Runyon, Kirby, primary

Published

2014

45. Slope Lineae

Author

Runyon, Kirby, primary, Ojha, Lujendra, additional, and Hargitai, Henrik, additional

Published

2014

46. Charon’s Far Side Geomorphology

Author

Beyer, Ross A., primary, Robbins, Stuart J., additional, Beddingfield, Chloe, additional, Bierson, Carver J., additional, Ennico, Kimberly, additional, Lauer, Tod R., additional, McKinnon, William B., additional, Moore, Jeffrey M., additional, Runyon, Kirby, additional, Olkin, Catherine B., additional, Schenk, Paul M., additional, Singer, Kelsi N., additional, Spencer, John R., additional, Stern, S. Alan, additional, Weaver, Harold A., additional, and Young, Leslie A., additional

Published

2021

47. Instrumentation Solutions and Constraints for a Long Duration Interstellar Probe Mission

Author

Cocoros, Alice, primary, McNutt, Ralph, additional, Brandt, Pontus, additional, Kinnison, James, additional, Jaskulek, Stephen, additional, Fountain, Glen, additional, Smith, Clayton, additional, Mandt, Kathleen, additional, Provornikova, Elena, additional, Lisse, Carey, additional, Runyon, Kirby, additional, Rymer, Abigail, additional, and Paul, Michael, additional

Published

2021

48. Photogeologic Map of the Perseverance Rover Field Site in Jezero Crater Constructed by the Mars 2020 Science Team

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Stack, Kathryn M., Williams, Nathan R., Calef, Fred, Sun, Vivian Z., Williford, Kenneth H., Farley, Kenneth A., Eide, Sigurd, Flannery, David, Hughes, Cory, Jacob, Samantha R., Kah, Linda C., Meyen, Forrest, Molina, Antonio, Nataf, Cathy Quantin, Rice, Melissa, Russell, Patrick, Scheller, Eva, Seeger, Christina H., Abbey, William J., Adler, Jacob B., Amundsen, Hans, Anderson, Ryan B., Angel, Stanley M., Arana, Gorka, Atkins, James, Barrington, Megan, Berger, Tor, Borden, Rose, Boring, Beau, Brown, Adrian, Carrier, Brandi L., Conrad, Pamela, Dypvik, Henning, Fagents, Sarah A., Gallegos, Zachary E., Garczynski, Brad, Golder, Keenan, Gomez, Felipe, Goreva, Yulia, Gupta, Sanjeev, Hamran, Svein-Erik, Hicks, Taryn, Hinterman, Eric Daniel, Horgan, Briony N., Hurowitz, Joel, Johnson, Jeffrey R., Lasue, Jeremie, Kronyak, Rachel E., Liu, Yang, Madariaga, Juan Manuel, Mangold, Nicolas, McClean, John, Miklusicak, Noah, Nunes, Daniel, Rojas, Corrine, Runyon, Kirby, Schmitz, Nicole, Scudder, Noel, Shaver, Emily, SooHoo, Jason G., Spaulding, Russell, Stanish, Evan, Tamppari, Leslie K., Tice, Michael M., Turenne, Nathalie, Willis, Peter A., Aileen Yingst, R., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Stack, Kathryn M., Williams, Nathan R., Calef, Fred, Sun, Vivian Z., Williford, Kenneth H., Farley, Kenneth A., Eide, Sigurd, Flannery, David, Hughes, Cory, Jacob, Samantha R., Kah, Linda C., Meyen, Forrest, Molina, Antonio, Nataf, Cathy Quantin, Rice, Melissa, Russell, Patrick, Scheller, Eva, Seeger, Christina H., Abbey, William J., Adler, Jacob B., Amundsen, Hans, Anderson, Ryan B., Angel, Stanley M., Arana, Gorka, Atkins, James, Barrington, Megan, Berger, Tor, Borden, Rose, Boring, Beau, Brown, Adrian, Carrier, Brandi L., Conrad, Pamela, Dypvik, Henning, Fagents, Sarah A., Gallegos, Zachary E., Garczynski, Brad, Golder, Keenan, Gomez, Felipe, Goreva, Yulia, Gupta, Sanjeev, Hamran, Svein-Erik, Hicks, Taryn, Hinterman, Eric Daniel, Horgan, Briony N., Hurowitz, Joel, Johnson, Jeffrey R., Lasue, Jeremie, Kronyak, Rachel E., Liu, Yang, Madariaga, Juan Manuel, Mangold, Nicolas, McClean, John, Miklusicak, Noah, Nunes, Daniel, Rojas, Corrine, Runyon, Kirby, Schmitz, Nicole, Scudder, Noel, Shaver, Emily, SooHoo, Jason G., Spaulding, Russell, Stanish, Evan, Tamppari, Leslie K., Tice, Michael M., Turenne, Nathalie, Willis, Peter A., and Aileen Yingst, R.

Abstract

The Mars 2020 Perseverance rover landing site is located within Jezero crater, a ∼50 km diameter impact crater interpreted to be a Noachian-aged lake basin inside the western edge of the Isidis impact structure. Jezero hosts remnants of a fluvial delta, inlet and outlet valleys, and infill deposits containing diverse carbonate, mafic, and hydrated minerals. Prior to the launch of the Mars 2020 mission, members of the Science Team collaborated to produce a photogeologic map of the Perseverance landing site in Jezero crater. Mapping was performed at a 1:5000 digital map scale using a 25 cm/pixel High Resolution Imaging Science Experiment (HiRISE) orthoimage mosaic base map and a 1 m/pixel HiRISE stereo digital terrain model. Mapped bedrock and surficial units were distinguished by differences in relative brightness, tone, topography, surface texture, and apparent roughness. Mapped bedrock units are generally consistent with those identified in previously published mapping efforts, but this study’s map includes the distribution of surficial deposits and sub-units of the Jezero delta at a higher level of detail than previous studies. This study considers four possible unit correlations to explain the relative age relationships of major units within the map area. Unit correlations include previously published interpretations as well as those that consider more complex interfingering relationships and alternative relative age relationships. The photogeologic map presented here is the foundation for scientific hypothesis development and strategic planning for Perseverance’s exploration of Jezero crater.

Published

2021

49. Long-Term Commitment to Explore and Sustain our Earth-Moon Environment

Author

Neal, Clive, primary, Pieters, Carle, additional, Abbud-Madrid, Angel, additional, Burns, Jack, additional, Hanna, Kerri Donaldson, additional, Dygert, Nick, additional, Ehlmann, Bethany, additional, Elkins-Tanton, Lindy, additional, Fagan, Amy, additional, Garrick-Bethell, Ian, additional, Grove, Timothy, additional, Head, James W., additional, Horanyi, Mihaly, additional, Jolliff, Brad, additional, Malaret, Erick, additional, Metzger, Philip, additional, Runyon, Kirby, additional, Shearer, Chip, additional, Tikoo, Sonia, additional, Watkins, Ryan N. Clegg, additional, Zacny, Kris, additional, and Zellner, Nicolle, additional

Published

2021

50. Comparative Planetology of Kuiper Belt Dwarf Planets Enabled by the Near-Term Interstellar Probe

Author

Runyon, Kirby, primary, Ahrens, Caitlin Joannah, additional, Beddingfield, Chloe B., additional, Cahill, Joshua T. S., additional, Cartwright, Richard, additional, Cohen, Ian, additional, Holler, Bryan, additional, Stryk, Ted, additional, Kollmann, Peter, additional, Kite, Edwin, additional, Keane, James Tuttle, additional, Cooper, John F., additional, Harman, Chester "Sonny", additional, Bannister, Michele, additional, Singer, Kelsi, additional, Stern, Alan, additional, Rymer, Abigail M., additional, Izenberg, Noam, additional, and Annex, Andrew, additional

Published

2021