Journey to Enceladus and Titan

Journey to Enceladus and Titan (JET) is an astrobiology mission concept to assess the habitability potential of Enceladus and Titan, moons of Saturn.

The JET orbiter concept was proposed in 2011 by the Jet Propulsion Laboratory to NASA's Discovery Program for its 13th mission. In September 2016 NASA will announce the winner of the competition and fund its development for a launch by the end of 2021.

Concept

Artist's impression of possible hydrothermal activity on Enceladus.

Enceladus is a small icy moon, seemingly similar in chemical makeup to comets,^[1] with jets or geysers of water erupting from its surface that might be connected to active hydrothermal vents at its subsurface water ocean floor,^{[2][3][4][5][6]} where the moon's ocean meets the underlying rock, a prime habitat for life.^[7][8] The geysers could provide easy access for sampling the moon's subsurface ocean, and if there is microbial life in it, ice particles from the sea could contain the evidence astrobiologists need to identify them.^[9] An organic-rich world, Titan has a methane cycle comparable in atmospheric and geological processes to Earth's water cycle.

Enceladus's south pole - Geysers spray water from many locations along the 'tiger stripes' feature.

The JET orbiter mission concept was proposed in 2011 by the Jet Propulsion Laboratory to NASA's Discovery Program Mission #13.^[10] During the orbiter's one-year mission, it would perform high-resolution mass spectroscopy mapping that would determine what processes have shaped and are shaping the moons, and it would permit assessment of the habitability potential of Enceladus and Titan.^[6][10]

In order to meet the $450 million cost cap, the orbiter would carry only two instruments. It would orbit Saturn and make a total of 16 flybys of Enceladus and Titan, the closest ones at 900 km from Titan's surface.^[10] In June 2015 NASA will announce a list of finalists for the current competition, followed by NASA's announcement of the winner in September 2016. The selected mission must launch by the end of 2021.^[11]

Objectives

Near-infrared radiation from the Sun reflecting off Titan's hydrocarbon seas.

The three goals of the mission are to determine the processes that have shaped and are shaping Enceladus and Titan, to assess their astrobiological potential, and to investigate their formation and evolution.^[10][12] If using an Atlas V rocket, JET would reach Saturn in 8.5 years using a Venus–Earth–Earth gravity assist trajectory.^[12]

At Enceladus, the mission will determine composition and flux of material in the plume, and will produce temperature maps of the faults, tectonics and interior dynamics.^[12] At Titan, it will characterize of the organic molecules in the upper atmosphere at different altitudes (> 900 km) and latitudes, and will produce high-resolution images for detailed study of features forming at different time-scales.^[12]

Payload

The orbiter payload consists of two instruments:^[10][12]

• Infrared camera: 'Titan Imaging and Geology, Enceladus Reconnaissance' (TIGER) — This high-heritage thermographic camera exploits infrared wavelengths to image through Titan's thick atmosphere and would image the heat of Enceladus's fractures known as 'tiger stripes', permitting a detailed thermal modeling. It would provide 10× better imaging resolution of Titan's surface than Cassini, yielding 50 m/pix images of 15% of Titan's surface.

• Mass spectrometer: 'Spectrometer for Titan and Enceladus Astrobiology Mission' (STEAM) — It would characterize elements and molecules, including complex organic molecules with 100× higher resolution, and 1000× better sensitivity than Cassini. STEAM is the Rosetta flight-spare.

See also

• Abiogenesis
• Astrobiology
• Discovery Program
• Enceladus Life Finder (ELF)
• Enceladus Explorer
• Europa Clipper
• Life Investigation For Enceladus (LIFE)
• THEO

References

1. Battersby, Stephen (March 26, 2008). "Saturn's moon Enceladus surprisingly comet-like". New Scientist. Retrieved April 16, 2015.
2. Ocean Within Enceladus May Harbor Hydrothermal Activity. March 11, 2015.
3. Platt, Jane; Bell, Brian (April 3, 2014). "NASA Space Assets Detect Ocean inside Saturn Moon". NASA. Retrieved 2014-04-03.
4. Iess, L.; Stevenson, D.J.; Parisi, M.; Hemingway, D.; Jacobson, R.A.; Lunine, J.I.; Nimmo, F.; Armstrong, J.w.; Asmar, S.w.; Ducci, M.; Tortora, P. (April 4, 2014). "The Gravity Field and Interior Structure of Enceladus". Science. 344 (6179): 78–80. Bibcode:2014Sci...344...78I. doi:10.1126/science.1250551. Retrieved 2014-04-03. {{cite journal}}: Unknown parameter |displayauthors= ignored (|display-authors= suggested) (help)
5. Amos, Jonathan (April 3, 2014). "Saturn's Enceladus moon hides 'great lake' of water". BBC News. Retrieved 2014-04-07.
6. Kane, Van (3 April 2014). "Discovery Missions for an Icy Moon with Active Plumes". The Planetary Society. Retrieved 2015-04-09.
7. Witze, Alexandra (March 11, 2015). "Hints of hot springs found on Saturnian moon". Nature News. Retrieved 2015-04-07.
8. Anderson, Paul Scott (March 13, 2015). "Cassini Finds Evidence for Hydrothermal Activity on Saturn's Moon Enceladus". AmericaSpace. Retrieved 2015-04-07.
9. Gronstal, Aaron (July 30, 2014). "Enceladus in 101 Geysers". NASA Astrobiology Institute. Retrieved 2015-04-08.
10. Sotin, C.; Altwegg, K.; Brown, R.H.; et al. (2011). JET: Journey to Enceladus and Titan (PDF). 42nd Lunar and Planetary Science Conference. Lunar and Planetary Institute.
11. Kane, Van (December 2, 2014). "Selecting the Next Creative Idea for Exploring the Solar System". Planetary Society. Retrieved 2015-02-10.
12. Matousek, Steve; Sotin, Christophe; Goebel, Dan; Lang, Jared (June 18–21, 2013). JET: Journey to Enceladus and Titan (PDF). Low Cost Planetary Missions Conference. California Institute of Technology.