Uranus Orbiter and Probe

Uranus Orbiter and Probe
	Mosaic of images of Uranus and its 5 major moons from Voyager 2
Mission type	Uranus orbiter
Operator	NASA
Mission duration	Cruise: 13.4 years ; Science phase: 4.5 years
Spacecraft properties
Launch mass	7,235 kg (15,950 lb)
Dry mass	2,756 kg (6,076 lb)
Payload mass	60.5 kg (133 lb) plus 19.7 kg (43 lb) atmospheric probe
Dimensions	Height: 7.1 m (23 ft); Diameter: less than 5 m (16 ft)
Power	735 W (0.986 hp) from 3 Mod1 Next-Generation Radioisotope thermoelectric generators
Start of mission
Launch date	not earlier than 2031
Rocket	Falcon Heavy Expendable (proposed)
Launch site	Kennedy Space Center Launch Complex 39A (proposed)
Flyby of Earth (gravity assist)
Closest approach	not earlier than 2033
Distance	450 km (280 mi)
Flyby of Jupiter (gravity assist)
Closest approach	not earlier than 2035
Distance	370,000 km (230,000 mi)
Uranus orbiter
Orbital insertion	not earlier than 2044
Uranus atmospheric probe
Atmospheric entry	not earlier than 2045
	Solar System Exploration program ← Europa Clipper Enceladus Orbilander →

The Uranus Orbiter and Probe is an orbiter mission concept to study Uranus and its moons.^[1] The orbiter would also deploy an atmospheric probe to characterize Uranus's atmosphere. The concept is being developed as a potential large strategic science mission for NASA. The science phase would last 4.5 years and include multiple flybys of each of the major moons.

The mission concept was selected as the highest priority Flagship-class mission by the 2023–2032 Planetary Science Decadal Survey, ahead of the Enceladus Orbilander.^[3]^[4] A Neptune orbiter mission concept, Neptune Odyssey, that would address many of the same scientific goals regarding ice giants was also considered, but for logistical and cost reasons a mission to Uranus was favored.

The original proposal targeted a launch in 2031 using a Falcon Heavy expendable launch vehicle with a gravity assist at Jupiter, allowing arrival at Uranus in 2044. In 2023, however, NASA announced that due to a shortfall in plutonium production a mid to late 2030s launch would be more likely.^[2]

^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j Simon, Amy; Nimmo, Francis; Anderson, Richard C. (7 June 2021). "Journey to an Ice Giant System: Uranus Orbiter and Probe". Planetary Mission Concept for the 2023–2032 Planetary Science Decadal Survey. NASA. Retrieved 1 May 2022.
^ ^a ^b Foust, Jeff (2023-05-03). "Plutonium availability constrains plans for future planetary missions". SpaceNews. Retrieved 2023-05-03.
^ Origins, Worlds, and Life: A Decadal Strategy for Planetary Science and Astrobiology 2023-2032 (Prepublication ed.). National Academies Press. 2022. p. 800. doi:10.17226/26522. ISBN 978-0-309-47578-5. S2CID 248283239. Retrieved 30 April 2022.
^ Foust, Jeff (19 April 2022). "Planetary science decadal endorses Mars sample return, outer planets missions". SpaceNews. Retrieved 19 April 2022.

[Concept-1] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j Simon, Amy; Nimmo, Francis; Anderson, Richard C. (7 June 2021). "Journey to an Ice Giant System: Uranus Orbiter and Probe". Planetary Mission Concept for the 2023–2032 Planetary Science Decadal Survey. NASA. Retrieved 1 May 2022.

[Faust-2] Foust, Jeff (2023-05-03). "Plutonium availability constrains plans for future planetary missions". SpaceNews. Retrieved 2023-05-03.

[2023decadal-3] Origins, Worlds, and Life: A Decadal Strategy for Planetary Science and Astrobiology 2023-2032 (Prepublication ed.). National Academies Press. 2022. p. 800. doi:10.17226/26522. ISBN 978-0-309-47578-5. S2CID 248283239. Retrieved 30 April 2022.

[Foust-4] Foust, Jeff (19 April 2022). "Planetary science decadal endorses Mars sample return, outer planets missions". SpaceNews. Retrieved 19 April 2022.

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