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Persephone: A Pluto-system Orbiter and Kuiper Belt Explorer

Authors :
Jj Kavelaars
Mark E. Holdridge
Jon Pineau
Jani Radebaugh
Kelsi N. Singer
David H. Napolillo
Leslie A. Young
B. Andrews
William B. McKinnon
H. Nair
Clint Apland
Carolyn M. Ernst
Chris J. Krupiarz
Anne J. Verbiscer
Jack Hunt
Clint L. Edwards
Carly Howett
Blair D. Fonville
Adam Thodey
Silvia Protopapa
Adam V. Crifasi
Mark E. Perry
Dan Gallagher
Doug Crowley
Bruce Williams
Karl B. Fielhauer
Stuart J. Robbins
A. R. Hendrix
S. Alan Stern
Stewart Bushman
Orenthal J. Tucker
James S. Kuhn
Robert J. Wilson
Francis Nimmo
Heather Elliott
J. R. Spencer
David P. Frankford
Fazle E. Siddique
Simon B. Porter
Rachel Sholder
Samantha R. Walters
Bryan J. Holler
J. C. Leary
Source :
The Planetary Science Journal. 2:75
Publication Year :
2021
Publisher :
American Astronomical Society, 2021.

Abstract

Persephone is a NASA concept mission study that addresses key questions raised by New Horizons’ encounters with Kuiper Belt objects (KBOs), with arguably the most important being, “Does Pluto have a subsurface ocean?” More broadly, Persephone would answer four significant science questions: (1) What are the internal structures of Pluto and Charon? (2) How have the surfaces and atmospheres in the Pluto system evolved? (3) How has the KBO population evolved? (4) What are the particles and magnetic field environments of the Kuiper Belt? To answer these questions, Persephone has a comprehensive payload, and it would both orbit within the Pluto system and encounter other KBOs. The nominal mission is 30.7 yr long, with launch in 2031 on a Space Launch System Block 2 rocket with a Centaur kick stage, followed by a 27.6 yr cruise powered by existing radioisotope electric propulsion and a Jupiter gravity assist to reach Pluto in 2058. En route to Pluto, Persephone would have one 50–100 km class KBO encounter before starting a 3.1-Earth-year orbital campaign of the Pluto system. The mission also includes the potential for an 8 yr extended mission, which would enable the exploration of another KBO in the 100–150 km size class. The mission payload includes 11 instruments: Panchromatic and Color High-Resolution Imager, Low-Light Camera, Ultra-Violet Spectrometer, Near-Infrared (IR) Spectrometer, Thermal IR Camera, Radio Frequency Spectrometer, Mass Spectrometer, Altimeter, Sounding Radar, Magnetometer, and Plasma Spectrometer. The nominal cost of this mission is $3.0 billion, making it a large strategic science mission.

Details

ISSN :
26323338
Volume :
2
Database :
OpenAIRE
Journal :
The Planetary Science Journal
Accession number :
edsair.doi...........de5b35d88399f9a4f907451ab66988b1