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1. Thin Ice Lithospheres and High Heat Flows on Europa From Large Impact Structure Ring-graben

Author

Singer, Kelsi N., McKinnon, William B., and Schenk, Paul M.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Craters are probes of planetary surface and interior properties. Here we measure depths, widths, and spacing of circumferential ring-graben surrounding the two largest multiring impact structures on Europa, Tyre and Callanish. We estimate formation conditions including the ice shell structure. The radial extension necessary to form these graben is thought to be caused by asthenospheric drag of warmer, more ductile ice and/or water flowing toward the excavated center of the crater, under a brittle-elastic lithospheric lid. Measurements of graben depths from stereo-photoclinometric digital elevation models result in estimates of displacement, strain, and stress experienced by the ice shell. Graben widths are used to estimate the intersection depth of the bounding normal faults, a quantity related to the brittle-ductile transition depth that approximates elastic shell thickness during crater collapse. Heat flows at the time of crater formation as well as ice lithosphere and total shell thickness are thus also constrained. Average widths and depths tend to decrease with increasing distance from the structure center, while inter-graben spacing generally increases. Varied assumptions yield plausible total conductive ice shell thickness estimates between 4-8 and 2.5-5 km for Tyre and Callanish, respectively, and heat flows of ~70-115 (+/-30) mW m^-2 for realistic thermal conductivities, consistent with other geophysical estimates for Europa. Higher heat flows are consistent with thin (<10 km), conductive ice shells and impact breaching, or penetration of the stagnant lid for a convecting ice shell. Callanish, geologically younger, formed in a time or region of greater heat flow than Tyre., Comment: 50 pages, 18 figures, 2 tables, published in JGR-Planets

Published
2024
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8. Index

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

19. Tectonics of Europa

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

20. Interior of Europa

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

31. Foreword

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

39. Preface

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

42. Cover

Author

Pappalardo, Robert T., McKinnon, William B., and Khurana, Krishan

Published
2009

43. Radar for Europa Assessment and Sounding: Ocean to Near-Surface (REASON)

Author

Blankenship, Donald D., Moussessian, Alina, Chapin, Elaine, Young, Duncan A., Wesley Patterson, G., Plaut, Jeffrey J., Freedman, Adam P., Schroeder, Dustin M., Grima, Cyril, Steinbrügge, Gregor, Soderlund, Krista M., Ray, Trina, Richter, Thomas G., Jones-Wilson, Laura, Wolfenbarger, Natalie S., Scanlan, Kirk M., Gerekos, Christopher, Chan, Kristian, Seker, Ilgin, Haynes, Mark S., Barr Mlinar, Amy C., Bruzzone, Lorenzo, Campbell, Bruce A., Carter, Lynn M., Elachi, Charles, Gim, Yonggyu, Hérique, Alain, Hussmann, Hauke, Kofman, Wlodek, Kurth, William S., Mastrogiuseppe, Marco, McKinnon, William B., Moore, Jeffrey M., Nimmo, Francis, Paty, Carol, Plettemeier, Dirk, Schmidt, Britney E., Zolotov, Mikhail Y., Schenk, Paul M., Collins, Simon, Figueroa, Harry, Fischman, Mark, Tardiff, Eric, Berkun, Andy, Paller, Mimi, Hoffman, James P., Kurum, Andy, Sadowy, Gregory A., Wheeler, Kevin B., Decrossas, Emmanuel, Hussein, Yasser, Jin, Curtis, Boldissar, Frank, Chamberlain, Neil, Hernandez, Brenda, Maghsoudi, Elham, Mihaly, Jonathan, Worel, Shana, Singh, Vik, Pak, Kyung, Tanabe, Jordan, Johnson, Robert, Ashtijou, Mohammad, Alemu, Tafesse, Burke, Michael, Custodero, Brian, Tope, Michael C., Hawkins, David, Aaron, Kim, Delory, Gregory T., Turin, Paul S., Kirchner, Donald L., Srinivasan, Karthik, Xie, Julie, Ortloff, Brad, Tan, Ian, Noh, Tim, Clark, Duane, Duong, Vu, Joshi, Shivani, Lee, Jeng, Merida, Elvis, Akbar, Ruzbeh, Duan, Xueyang, Fenni, Ines, Sanchez-Barbetty, Mauricio, Parashare, Chaitali, Howard, Duane C., Newman, Julie, Cruz, Marvin G., Barabas, Neil J., Amirahmadi, Ahmadreza, Palmer, Brendon, Gawande, Rohit S., Milroy, Grace, Roberti, Rick, Leader, Frank E., West, Richard D., Martin, Jan, Venkatesh, Vijay, Adumitroaie, Virgil, Rains, Christine, Quach, Cuong, Turner, Jordi E., O’Shea, Colleen M., Kempf, Scott D., Ng, Gregory, Buhl, Dillon P., and Urban, Timothy J.

Published
2024
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44. Science Overview of the Europa Clipper Mission

Author

Pappalardo, Robert T., Buratti, Bonnie J., Korth, Haje, Senske, David A., Blaney, Diana L., Blankenship, Donald D., Burch, James L., Christensen, Philip R., Kempf, Sascha, Kivelson, Margaret G., Mazarico, Erwan, Retherford, Kurt D., Turtle, Elizabeth P., Westlake, Joseph H., Paczkowski, Brian G., Ray, Trina L., Kampmeier, Jennifer, Craft, Kate L., Howell, Samuel M., Klima, Rachel L., Leonard, Erin J., Matiella Novak, Alexandra, Phillips, Cynthia B., Daubar, Ingrid J., Blacksberg, Jordana, Brooks, Shawn M., Choukroun, Mathieu N., Cochrane, Corey J., Diniega, Serina, Elder, Catherine M., Ernst, Carolyn M., Gudipati, Murthy S., Luspay-Kuti, Adrienn, Piqueux, Sylvain, Rymer, Abigail M., Roberts, James H., Steinbrügge, Gregor, Cable, Morgan L., Scully, Jennifer E. C., Castillo-Rogez, Julie C., Hay, Hamish C. F. C., Persaud, Divya M., Glein, Christopher R., McKinnon, William B., Moore, Jeffrey M., Raymond, Carol A., Schroeder, Dustin M., Vance, Steven D., Wyrick, Danielle Y., Zolotov, Mikhail Y., Hand, Kevin P., Nimmo, Francis, McGrath, Melissa A., Spencer, John R., Lunine, Jonathan I., Paty, Carol S., Soderblom, Jason M., Collins, Geoffrey C., Schmidt, Britney E., Rathbun, Julie A., Shock, Everett L., Becker, Tracy C., Hayes, Alexander G., Prockter, Louise M., Weiss, Benjamin P., Hibbitts, Charles A., Moussessian, Alina, Brockwell, Timothy G., Hsu, Hsiang-Wen, Jia, Xianzhe, Gladstone, G. Randall, McEwen, Alfred S., Patterson, G. Wesley, McNutt, Jr., Ralph L., Evans, Jordan P., Larson, Timothy W., Cangahuala, L. Alberto, Havens, Glen G., Buffington, Brent B., Bradley, Ben, Campagnola, Stefano, Hardman, Sean H., Srinivasan, Jeffrey M., Short, Kendra L., Jedrey, Thomas C., St. Vaughn, Joshua A., Clark, Kevin P., Vertesi, Janet, and Niebur, Curt

Published
2024
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45. 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
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47. Anomalous Flux in the Cosmic Optical Background Detected With New Horizons Observations

Author

Lauer, Tod R., Postman, Marc, Spencer, John R., Weaver, Harold A., Stern, S. Alan, Gladstone, G. Randall, Binzel, Richard P., Britt, Daniel T., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Grundy, W. M., Horányi, Mihaly, Kavelaars, J. J., Linscott, Ivan R., Lisse, Carey M., McKinnon, William B., McNutt, Ralph L., Moore, Jeffrey M., Núñez, Jorge I., Olkin, Catherine B., Parker, Joel W., Porter, Simon B., Reuter, Dennis C., Robbins, Stuart J., Schenk, Paul M., Showalter, Mark R., Singer, Kelsi N., Verbiscer, Anne. J., and Young, Leslie A.

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Cosmology and Nongalactic Astrophysics
Abstract

We used New Horizons LORRI images to measure the optical-band ($0.4\lesssim\lambda\lesssim0.9{\rm\mu m}$) sky brightness within a high galactic-latitude field selected to have reduced diffuse scattered light from the Milky Way galaxy (DGL), as inferred from the IRIS all-sky $100~\mu$m map. We also selected the field to significantly reduce the scattered light from bright stars (SSL) outside the LORRI field. Suppression of DGL and SSL reduced the large uncertainties in the background flux levels present in our earlier New Horizons COB results. The raw total sky level, measured when New Horizons was 51.3 AU from the Sun, is $24.22\pm0.80{\rm ~nW ~m^{-2} ~sr^{-1}}.$ Isolating the COB contribution to the raw total required subtracting scattered light from bright stars and galaxies, faint stars below the photometric detection-limit within the field, and the hydrogen plus ionized-helium two-photon continua. This yielded a highly significant detection of the COB at ${\rm 16.37\pm 1.47 ~nW ~m^{-2} ~sr^{-1}}$ at the LORRI pivot wavelength of 0.608 $\mu$m. This result is in strong tension with the hypothesis that the COB only comprises the integrated light of external galaxies (IGL) presently known from deep HST counts. Subtraction of the estimated IGL flux from the total COB level leaves a flux component of unknown origin at ${\rm 8.06\pm1.92 ~nW ~m^{-2} ~sr^{-1}}.$ Its amplitude is equal to the IGL., Comment: Accepted for publication in the Astrophysical Journal Letters

Published
2022
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48. The Dark Side of Pluto

Author

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

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

During its departure from Pluto, New Horizons used its LORRI camera to image a portion of Pluto's southern hemisphere that was in a decades-long seasonal winter darkness, but still very faintly illuminated by sunlight reflected by Charon. Recovery of this faint signal was technically challenging. The bright ring of sunlight forward-scattered by haze in the Plutonian atmosphere encircling the nightside hemisphere was severely overexposed, defeating the standard smeared-charge removal required for LORRI images. Reconstruction of the overexposed portions of the raw images, however, allowed adequate corrections to be accomplished. The small solar elongation of Pluto during the departure phase also generated a complex scattered-sunlight background in the images that was three orders of magnitude stronger than the estimated Charon-light flux (the Charon-light flux is similar to the flux of moonlight on Earth a few days before first quarter). A model background image was constructed for each Pluto image based on principal component analysis (PCA) applied to an ensemble of scattered-sunlight images taken at identical Sun-spacecraft geometry to the Pluto images. The recovered Charon-light image revealed a high-albedo region in the southern hemisphere. We argue that this may be a regional deposit of N_2 or CH_4 ice. The Charon-light image also shows that the south polar region currently has markedly lower albedo than the north polar region of Pluto, which may reflect the sublimation of N_2 ice or the deposition of haze particulates during the recent southern summer., Comment: 24 pages, 10 figures, published in the Planetary Science Journal

Published
2021

49. Investigating Europa’s Habitability with the Europa Clipper

Author

Vance, Steven D., Craft, Kathleen L., Shock, Everett, Schmidt, Britney E., Lunine, Jonathan, Hand, Kevin P., McKinnon, William B., Spiers, Elizabeth M., Chivers, Chase, Lawrence, Justin D., Wolfenbarger, Natalie, Leonard, Erin J., Robinson, Kirtland J., Styczinski, Marshall J., Persaud, Divya M., Steinbrügge, Gregor, Zolotov, Mikhail Y., Quick, Lynnae C., Scully, Jennifer E. C., Becker, Tracy M., Howell, Samuel M., Clark, Roger N., Dombard, Andrew J., Glein, Christopher R., Mousis, Olivier, Sephton, Mark A., Castillo-Rogez, Julie, Nimmo, Francis, McEwen, Alfred S., Gudipati, Murthy S., Jun, Insoo, Jia, Xianzhe, Postberg, Frank, Soderlund, Krista M., and Elder, Catherine M.

Published
2023
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50. Pits, Uplifts and Small Chaos Features on Europa: Morphologic and Morphometric Evidence for Intrusive Upwelling and Lower Limits to Ice Shell Thickness

Author

Singer, Kelsi N., McKinnon, William B., and Schenk, Paul M.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

One of the clearest but unresolved questions for Europa is the thickness of its icy shell. Europa's surface is resplendent with geological features that bear on this question, and ultimately on its interior, geological history, and astrobiological potential. We characterize the size and topographic expression of circular and subcircular features created by endogenic thermal and tectonic disturbances on Europa: pits, uplifts, and small, subcircular chaos. We utilize the medium-resolution Galileo regional maps (RegMaps), as well as high-resolution regions, digital elevation models derived from albedo-controlled photoclinometry, and in some cases stereo-controlled photoclinometry. While limited in extent, the high-resolution images are extremely valuable for detecting smaller features and for overall geomorphological analysis. A peak in the size-distribution for all features is found at ~5-6 km in diameter and no pits smaller than 3.3 km in diameter were found in high resolution images. Additionally, there is a trend for larger pits to be deeper, and larger uplifts to be higher. Our data support a diapiric or intracrustal sill interpretation (as opposed to purely non-intrusive, melt-through models) and place a lower limit on ice shell thickness at the time of feature formation of 3-to-8 km, assuming isostasy and depending on the composition of the ice and underlying ocean.

Published
2021
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