Brent Sherwood scite author profile

Ceres, the most water-rich body in the inner solar system after Earth, has recently been recognized to have astrobiological importance. Chemical and physical measurements obtained by the Dawn mission enabled the quantification of key parameters, which helped to constrain the habitability of the inner solar system's only dwarf planet. The surface chemistry and internal structure of Ceres testify to a protracted history of reactions between liquid water, rock, and likely organic compounds. We review the clues on chemical composition, temperature, and prospects for long-term occurrence of liquid and chemical gradients. Comparisons with giant planet satellites indicate similarities both from a chemical evolution standpoint and in the physical mechanisms driving Ceres' internal evolution.

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Returning Samples From Enceladus for Life Detection

Neveu

Anbar

Davila

et al. 2020

Front. Astron. Space Sci.

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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.

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Recent improvements in JPL's mission formulation process

Leising

Sherwood

Adler

et al. 2010

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Strategic map for exploring the ocean-world Enceladus

Sherwood

2016

Acta Astronautica

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Principles for a practical Moon base

Sherwood

2019

Acta Astronautica

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Forward Contamination of Ocean Worlds: A Stakeholder Conversation

2019

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Program options to explore ocean worlds

et al. 2018

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JPL Innovation Foundry

Sherwood

McCleese

2013

Acta Astronautica

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Brent Sherwood

Ceres: Astrobiological Target and Possible Ocean World

Returning Samples From Enceladus for Life Detection

Recent improvements in JPL's mission formulation process

Strategic map for exploring the ocean-world Enceladus

Principles for a practical Moon base

Forward Contamination of Ocean Worlds: A Stakeholder Conversation

Program options to explore ocean worlds

JPL Innovation Foundry

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