The Planetary Science Journal (Jan 2023)

Astrobiology eXploration at Enceladus (AXE): A New Frontiers Mission Concept Study

  • K. Marshall Seaton,
  • Szilárd Gyalay,
  • Gaia Stucky de Quay,
  • Ethan R. Burnett,
  • C. Adeene Denton,
  • Bryce Doerr,
  • Kamak Ebadi,
  • Stephanie Eckert,
  • Ian. T. W. Flynn,
  • Casey I. Honniball,
  • Shayna Hume,
  • Corbin L. Kling,
  • Julian C. Marohnic,
  • Julia Milton,
  • Claire A. Mondro,
  • Raquel G. Nuno,
  • Caoimhe M. Rooney,
  • Beck E. Strauss,
  • Alfred Nash,
  • Jennifer E. C. Scully

DOI
https://doi.org/10.3847/PSJ/acd119
Journal volume & issue
Vol. 4, no. 6
p. 116

Abstract

Read online

The Saturnian moon Enceladus presents a unique opportunity to sample the contents of a subsurface liquid water ocean in situ via the continuous plume formed over its south polar terrain using a multi-flyby mission architecture. Previous analyses of the plume’s composition by Cassini revealed an energy-rich system laden with salts and organic compounds, representing an environment containing most of the ingredients for life as we know it. Following in the footsteps of the Cassini-Huygens mission, we present Astrobiology eXploration at Enceladus (AXE), a New Frontiers class Enceladus mission concept study carried out during the 2021 NASA Planetary Science Summer School program at the Jet Propulsion Laboratory, California Institute of Technology. We demonstrate that a scientifically compelling geophysical and life-detection mission to Enceladus can be carried out within the constraints of a New Frontiers-5 cost cap using a modest instrument suite, requiring only a narrow angle, high-resolution telescopic imager, a mass spectrometer, and a high-gain antenna for radio communications and gravity science measurements. Using a multi-flyby mission architecture, AXE would evaluate the habitability and potential for life at Enceladus through a synergistic combination of in situ chemical analysis measurements aimed at directly detecting the presence of molecular biosignatures, along with geophysical and geomorphological investigations to contextualize chemical biosignatures and further evaluate the habitability of Enceladus over geologic time.

Keywords