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1. Impacts on Ocean Worlds Are Sufficiently Frequent and Energetic to Be of Astrobiological Importance

Author

Shannon M. MacKenzie, Alexandra Pontefract, R. Terik Daly, Jacob J. Buffo, Gordon R. Osinski, Christopher J. Cline II, Mark J. Cintala, Kathleen L. Craft, Mallory J. Kinczyk, Joshua Hedgepeth, Sarah M. Hörst, Abel Méndez, Ben K. D. Pearce, Angela M. Stickle, and Steven D. Vance

Subjects
Titan, Enceladus, Europa, Impact phenomena, Craters, Astronomy, QB1-991
Abstract

Evidence for the beneficial role of impacts in the creation of urable or habitable environments on Earth prompts the question of whether meteorite impacts could play a similar role at other potentially urable/habitable worlds like Enceladus, Europa, and Titan. In this work, we demonstrate that to first order, impact conditions on these worlds are likely to have been consistent with the survival of organic compounds and/or sufficient for promoting synthesis in impact melt. We also calculate melt production and freezing times for crater sizes found at Enceladus, Europa, and Titan and find that even the smallest craters at these worlds offer the potential to study the evolution of chemical pathways within impact melt. These first-order calculations point to a critical need to investigate these processes at higher fidelity with lab experiments, sophisticated thermodynamic and chemical modeling, and, eventually, in situ investigations by missions.

Published
2024
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2. Toward Prebiotic Chemistry on Titan: Impact Experiments on Organic Haze Particles

Author

Ben K. D. Pearce, Sarah M. Hörst, Christopher J. Cline, Mark J. Cintala, Chao He, Joshua A. Sebree, Shannon M. MacKenzie, R. Terik Daly, Alexandra J. Pontefract, and Cara Pesciotta

Subjects
Astrobiology, Pre-biotic astrochemistry, Shocks, Titan, Planetary atmospheres, Planetary science, Astronomy, QB1-991
Abstract

Impacts are critical to producing the aqueous environments necessary to stimulate prebiotic chemistry on Titan’s surface. Furthermore, organic hazes resting on the surface are a likely feedstock of biomolecules. In this work, we conduct impact experiments on laboratory-produced organic haze particles and haze/sand mixtures and analyze these samples for life’s building blocks. Samples of unshocked haze and sand particles are also analyzed to determine the change in biomolecule concentrations and distributions from shocking. Across all samples, we detect seven nucleobases, nine proteinogenic amino acids, and five other biomolecules (e.g., urea) using a blank subtraction procedure to eliminate signals due to contamination. We find that shock pressures of 13 GPa variably degrade nucleobases, amino acids, and a few other organics in haze particles and haze/sand mixtures; however, certain individual biomolecules become enriched or are even produced from these events. Xanthine, threonine, and aspartic acid are enriched or produced in impact experiments containing sand, suggesting these minerals may catalyze the production of these biomolecules. On the other hand, thymine and isoleucine/norleucine are enriched or produced in haze samples containing no sand, suggesting catalytic grains are not necessary for all impact shock syntheses. Uracil, glycine, proline, cysteine, and tyrosine are the most unstable to impact-related processing. These experiments suggest that impacts alter biomolecule distributions on Titan’s surface, and that organic hazes co-occurring with fine-grained material on the surface may provide an initial source for further prebiotic chemistry on Titan.

Published
2024
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3. The root of anomalously specular reflections from solid surfaces on Saturn’s moon Titan

Author

Jason D. Hofgartner, Alexander G. Hayes, Donald B. Campbell, Jonathan I. Lunine, Gregory J. Black, Shannon M. MacKenzie, Samuel P. D. Birch, Charles Elachi, Randolph D. Kirk, Alice Le Gall, Ralph D. Lorenz, and Stephen D. Wall

Subjects
Science
Abstract

Anomalously specular radar reflections (ASRR) from Titan’s tropical region were interpreted earlier as evidence for liquid surfaces, but the Cassini spacecraft did not observe lakes/seas at the anomalously specular locations. Here, the authors show that ASRR originate from one terrain unit, likely paleolakes/paleoseas.

Published
2020
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4. Returning Samples From Enceladus for Life Detection

Author

Marc Neveu, Ariel D. Anbar, Alfonso F. Davila, Daniel P. Glavin, Shannon M. MacKenzie, Charity M. Phillips-Lander, Brent Sherwood, Yoshinori Takano, Peter Williams, and Hajime Yano

Subjects
Enceladus, astrobiology, sample return, life detection, ocean worlds, icy satellites, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Evidence suggests that Saturn's icy moon Enceladus has a subsurface ocean that sources plumes of water vapor and ice vented to space from its south pole. In situ analyses of this material by the Cassini spacecraft have shown that the ocean contains key ingredients for life (elements H, C, N, O and possibly S; simple and complex organic compounds; chemical disequilibria at water-rock interfaces; clement temperature, pressure, and pH). The Cassini discoveries make Enceladus' interior a prime locale for life detection beyond Earth. Scant material exchange with the inner Solar System makes it likely that such life would have emerged independently of life on Earth. Thus, its discovery would illuminate life's universal characteristics. The alternative result of an upper bound on a detectable biosphere in an otherwise habitable environment would likewise considerably advance our understanding of the prevalence of life beyond Earth. Here we outline the rationale for returning vented ocean samples, accessible from Enceladus' surface or low altitudes, to Earth for life detection. Returning samples allows analyses using laboratory instruments that cannot be flown, with decades or more to adapt and repeat analyses. We describe an example set of measurements to estimate the amount of sample to be returned and discuss possible mission architectures and collection approaches. We then turn to the challenges of preserving sample integrity and implementing planetary protection policy. We conclude by placing such a mission in the broader context of Solar System exploration.

Published
2020
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5. Prospects for Detecting Volcanic Events with Microwave Radiometry

Author

Shannon M. MacKenzie and Ralph D. Lorenz

Subjects
volcanoes, SMAP, microwave radiometry, Science
Abstract

Identifying volcanic activity on worlds with optically thick atmospheres with passive microwave radiometry has been proposed as a means of skirting the atmospheric interference that plagues near infrared observations. By probing deeper into the surface, microwave radiometers may also be sensitive to older flows and thus amenable for investigations where repeat observations are infrequent. In this investigation we explore the feasibility of this tactic using data from the Soil Moisture Active Passive (SMAP) mission in three case studies: the 2018 Kilauea eruption, the 2018 Oct-Nov eruption at Fuego, and the ongoing activity at Erta Ale in Ethiopia. We find that despite SMAP’s superior spatial resolution, observing flows that are small fractions of the observing footprint are difficult to detect—even in resampled data products. Furthermore, the absorptivity of the flow, which can be temperature dependent, can limit the depths to which SMAP is sensitive. We thus demonstrate that the lower limit of detectability at L-band (1.41 GHz) is in practice higher than expected from first principles.

Published
2020
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6. Planetary protection assessment of radioisotope thermoelectric generator (RTG)-powered landed missions to ocean worlds: application to Enceladus

Author

Marc Neveu, Robert F. Coker, Ralph D. Lorenz, Shannon M. MacKenzie, Jonathan I. Lunine, and Alfonso F. Davila

Subjects
Earth Resources And Remote Sensing
Abstract

Landed missions to icy worlds with a subsurface liquid water ocean must meet planetary protection requirements, and ensure a sufficiently small likelihood of any microorganism-bearing part of the landed element reaching the ocean. A higher bound on this likelihood is set by the potential for radioisotope thermoelectric generator (RTG) power sources, the hottest possible landed element, to melt through the ice shell and reach the ocean. Here, we quantify this potential as a function of three key parameters: surface temperature, ice shell thickness (i.e., heat flux through the shell), and thickness of a porous (insulating) snow or regolith cover. Although the model we describe can be applied to any ocean world, we present results in the context of a landed mission concept to the south polar terrain of Saturn’s moon Enceladus. In this particular context, we discuss planetary protection considerations for landing site selection. The likelihood of forward microbial contamination of Enceladus’ ocean by an RTG-powered landed mission can be made sufficiently low to not undermine compliance with planetary protection policy.

Published
2022
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7. Science Objectives for Flagship-Class Mission Concepts for the Search for Evidence of Life at Enceladus

Author

Shannon M. MacKenzie, Marc Neveu, Alfonso F. Davila, Jonathan I. Lunine, Morgan L. Cable, Charity M. Phillips-Lander, Jennifer L. Eigenbrode, J. Hunter Waite, Kate L. Craft, Jason D. Hofgartner, Chris P. McKay, Christopher R. Glein, Dana Burton, Samuel P. Kounaves, Richard A. Mathies, Steven D. Vance, Michael J. Malaska, Robert Gold, Christopher R. German, Krista M. Soderlund, Peter Willis, Caroline Freissinet, Alfred S. McEwen, John Robert Brucato, Jean-Pierre P. de Vera, Tori M. Hoehler, and Jennifer Heldmann

Subjects
Exobiology
Abstract

Cassini revealed that Saturn's Moon Enceladus hosts a subsurface ocean that meets the accepted criteria for habitability with bio-essential elements and compounds, liquid water, and energy sources available in the environment. Whether these conditions are sufficiently abundant and collocated to support life remains unknown and cannot be determined from Cassini data. However, thanks to the plume of oceanic material emanating from Enceladus’ south pole, a new mission to Enceladus could search for evidence of life without having to descend through kilometers of ice. In this article, we outline the science motivations for such a successor to Cassini, choosing the primary science goal to be determining whether Enceladus is inhabited and assuming a resource level equivalent to NASA's Flagship-class missions. We selected a set of potential biosignature measurements that are complementary and orthogonal to build a robust case for any life detection result. This result would be further informed by quantifications of the habitability of the environment through geochemical and geophysical investigations into the ocean and ice shell crust. This study demonstrates that Enceladus’ plume offers an unparalleled opportunity for in situ exploration of an Ocean World and that the planetary science and astrobiology community is well equipped to take full advantage of it in the coming decades.

Published
2022
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9. The Enceladus Orbilander Mission Concept: Balancing Return and Resources in the Search for Life

Author

Shannon M. MacKenzie, Marc Neveu, Alfonso F Davila, Jonathan I Lunine, Kathleen L Craft, Morgan L Cable, Charity M Phillips-Lander, Jason D Hofgartner, Jennifer L Eigenbrode, J Hunter Waite, Jr, Christopher R Glein, Robert Gold, Peter J Greenauer, Karen Kirby, Christopher Bradburne, Samuel P Kounaves, Michael J Malaska, Frank Postberg, G Wesley Patterson, Carolyn Porco, Jorge I Nunez, Chris German, Julie A Huber, Christopher P Mckay, Jean-Pierre de Vera, John Robert Brucato, and Linda Joyce Spilker

Subjects
Lunar And Planetary Science And Exploration
Abstract

Enceladus’s long-lived plume of ice grains and water vapor makes accessing oceanic material readily achievable from orbit (around Saturn or Enceladus) and from the moon’s surface. In preparation for the National Academies of Sciences, Engineering and Medicine 2023–2032 Planetary Science and Astrobiology Decadal Survey, we investigated four architectures capable of collecting and analyzing plume material from orbit and/or on the surface to address the most pressing questions at Enceladus: Is the subsurface ocean inhabited? Why, or why not? Trades specific to these four architectures were studied to allow an evaluation of the science return with respect to investment. The team found that Orbilander, a mission concept that would first orbit and then land on Enceladus, represented the best balance. Orbilander was thus studied at a higher fidelity, including a more detailed science operations plan during both orbital and landed phases, landing site characterization and selection analyses, and landing procedures. The Orbilander mission concept demonstrates that scientifically compelling but resource-conscious Flagship-class missions can be executed in the next decade to search for life at Enceladus.

Published
2021
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11. Spotlight Column

Author

Alena M, Baquet-Simpson, Kelly Jean Thomas, Craig, Shannon M, MacKenzie, Hillary V, Miller, Hannah, Yang, Robin P, Foreman, Kerry A, Martinez, Sherrie L, McNutt, Dorothea J, Verbrugge, and Jamie S, Sharp

Subjects
Public Health, Environmental and Occupational Health
Published
2022
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12. Encealdus Orbilander: A Flagship Mission Concept for Astrobiology

Author

Shannon M MacKenzie, Karen W Kirby, Peter J Greenauer, Marc Neveu, Rob Gold, Alfonso Davila, Jonathan I Lunine, Morgan Cable, Kate Craft, Jennifer Eigenbrode, Christopher Glein, Jason Hofgartner, Christopher Mckay, Charity Phillips-Lander, Hunter Waite, Dana Burton, Helmut Seifert, Jeff Boye, Spencer Brock, Michelle Chen, Rob Coker, Grace Colonel, Tom Criss, and Doug Crowley

Subjects
Lunar And Planetary Science And Exploration
Abstract

"Whether life exists beyond Earth remains a fundamental question driving our exploration of the Solar System. At Saturn’s moon Enceladus, plumes of oceanic material vented into space allow the investigation of the astrobiological potential of an ocean world, hinted at by Cassini, without the necessity of drilling through kilometers of ice crust. The Enceladus Orbilander is a flagship ($2.56B in fiscal year 2025 dollars) mission concept created for the 2023–2033 Planetary Science Decadal Survey. Orbilander takes full advantage of the opportunity provided by Enceladus’ plumes to search for signs of life. A single spacecraft both orbits and lands, capturing samples from four distinct reservoirs offered by the plumes. These samples, both particulate and vapor, are then analyzed by the Life Detection Suite (LDS), a set of five instruments conducting complementary and orthogonal biosignature-seeking measurements. To provide the context that specifically enhances interpretation of LDS measurements, geochemical and geophysical investigations are conducted both in orbit and on the surface. These reveal the physio-chemical state of the ocean and core as well as the processes involved in ejection of plume material and how these affect the ocean material analyzed by the LDS. The Orbilander can be delivered to the Saturn system via several launch vehicle and trajectory options, including a direct trajectory (7-year cruise), a ∆V-EGA trajectory (9-year cruise) and several options using an inner cruise with Venus and Earth flybys (10-year cruise). Upon Saturn Orbit Insertion, a 4-year moon tour pumps down the Orbilander’s orbit to intercept Enceladus. The most optimal arrival times balance the Jupiter flyby opportunities of the late 2030s and solar illumination at the Enceladus high southern latitudes where plume material is most abundant. This mission concept therefore targets project start in 2030. Upon Enceladus Orbit Insertion, the Orbilander begins a 1.5-year-long campaign of landing site reconnaissance, remote sensing science, and collecting sufficient plume sample to run all but one of the LDS measurements. After successful landing, the Orbilander spends 2 years on the surface conducting multiple LDS measurements with all five instruments on actively and passively collected plume material, as well as seismic investigations. The schedule laid out here is well-defined, but the mission also has operational and resource flexibility should additional reconnaissance be needed. As part of the design study, mission and development risks were identified and mitigation strategies proposed. Technologies key to achieving the life detection science objectives include instrumentation matured under programs like COLDTech and ICEE-2, such as aspects of the sampling system and microfluidic devices, as well as well-known techniques like high-resolution and separation-capable mass spectrometers. Autonomous onboard navigation is planned to maintain a halo orbit around Enceladus to enable passive sampling from orbit as well as reconnaissance measurements for use in site selection and landing. Terrain relative navigation is included to ensure safe landing, given that targeted areas may contain landing hazards. Continued development of radioisotope thermoelectric generator (RTG) technology and long-life batteries is essential for this long duration mission. The Enceladus Orbilander represents an optimal point in the trade space of science value versus cost, taking advantage of the extensive knowledge of Enceladus provided by Cassini, how well Enceladus lends itself to a search for life in material from its ocean, and the flexibility afforded by the innovative design developed by the APL team. By taking full advantage of Enceladus’ plumes both in orbit and on the surface, Orbilander represents a robust search for life with complementary and orthogonal biosignatures as well as contextual geophysical and geochemical measurements, determining not only whether Enceladus is inhabited (at levels up to 500,000× scarcer than in Earth’s oceans) but also why. "

Published
2020

13. The Science Case for a Return to Enceladus

Author

Morgan L. Cable, Carolyn Porco, Christopher R. Glein, Christopher R. German, Shannon M. MacKenzie, Marc Neveu, Tori M. Hoehler, Amy E. Hofmann, Amanda R. Hendrix, Jennifer Eigenbrode, Frank Postberg, Linda J. Spilker, Alfred McEwen, Nozair Khawaja, J. Hunter Waite, Peter Wurz, Jörn Helbert, Ariel Anbar, Jean-Pierre de Vera, and Jorge Núñez

Published
2021
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14. Titan: Earth-like on the Outside, Ocean World on the Inside

Author

Shannon M. MacKenzie, Samuel P. D. Birch, Sarah Hörst, Christophe Sotin, Erika Barth, Juan M. Lora, Melissa G. Trainer, Paul Corlies, Michael J. Malaska, Ella Sciamma-O’Brien, Alexander E. Thelen, Elizabeth Turtle, Jani Radebaugh, Jennifer Hanley, Anezina Solomonidou, Claire Newman, Leonardo Regoli, Sébastien Rodriguez, Benôit Seignovert, Alexander G. Hayes, Baptiste Journaux, Jordan Steckloff, Delphine Nna-Mvondo, Thomas Cornet, Maureen Y. Palmer, Rosaly M. C. Lopes, Sandrine Vinatier, Ralph Lorenz, Conor Nixon, Ellen Czaplinski, Jason W. Barnes, Ed Sittler, and Andrew Coates

Published
2021
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