Dragonfly is a planned
NASA mission to send a robotic
rotorcraft to the surface of
Titan, the largest moon of Saturn. It is planned to be launched in July 2028 and arrive in 2034. It would be the first aircraft on Titan and is intended to make the first powered and fully controlled atmospheric flight on any
moon, with the intention of studying prebiotic chemistry and
extraterrestrial habitability. It would then use its vertical takeoffs and landings (
VTOL) capability to move between exploration sites.[6][7][8]
Titan is unique in having an abundant, complex, and diverse carbon-rich chemistry and a surface dominated by water and ice, with an interior water ocean, making it a high-priority target for
astrobiology and
origin of life studies.[6] The mission was proposed in April 2017 to NASA's
New Frontiers program by the
Johns Hopkins Applied Physics Laboratory (APL), and was selected as one of two finalists (out of twelve proposals) in December 2017 to further refine the mission's concept.[9][10] On 27 June 2019, Dragonfly was selected to become the fourth mission in the New Frontiers program.[11][12] In April 2024 the mission was confirmed and moved to its final development stages.[13]
Overview
Dragonfly is an astrobiology mission to Titan to assess its microbial habitability and study its prebiotic chemistry at various locations. Dragonfly is designed to perform controlled flights and vertical takeoffs and landings between locations. The mission is to involve flights to multiple different locations on the surface, which allows sampling of diverse regions and geological contexts.[3][14]
Titan is a compelling astrobiology target because its surface contains abundant complex carbon-rich chemistry and because both liquid water (transient) and liquid hydrocarbons can occur on its surface, possibly forming a prebiotic
primordial soup.[15]
A successful flight of Dragonfly would make it the second rotorcraft to fly on a celestial body other than Earth, following the success of
Ingenuity, a technology demonstration
UAV helicopter, which landed on Mars with the
Perseverance rover on 18 February 2021 as part of the
Mars 2020 mission and first achieved powered flight on 19 April 2021.[16][17][18]
History
The initial Dragonfly conception took place over a dinner conversation between scientists Jason W. Barnes of Department of Physics,
University of Idaho, (who had previously made the
AVIATR proposal for a Titan aircraft) and
Ralph Lorenz of
Johns Hopkins UniversityApplied Physics Laboratory, and it took 15 months to make it a detailed mission proposal.[19] The principal investigator is
Elizabeth Turtle, a planetary scientist at the Johns Hopkins Applied Physics Laboratory.[14]
The Dragonfly mission builds on several earlier studies of Titan mobile aerial exploration, including the 2007 Titan Explorer Flagship study,[20] which advocated a
Montgolfier balloon for regional exploration, and AVIATR, an airplane concept considered for the Discovery program.[3] The concept of a rotorcraft lander that flew on battery power, recharged during the 8-Earth-day Titan night from a radioisotope power source, was proposed by Lorenz in 2000.[21] More recent discussion has included a 2014 Titan rotorcraft study by Larry Matthies, at the
Jet Propulsion Laboratory, that would have a small rotorcraft deployed from a lander or a balloon.[22] The hot-air balloon concepts would have used the heat from a
radioisotope thermoelectric generator (RTG).[23]
Dragonfly is to use its multi-rotor vehicle to transport its instrument suite to multiple locations to make measurements of surface composition, atmospheric conditions, and geologic processes.[24]
Dragonfly and CAESAR, a comet sample return mission to
67P/Churyumov–Gerasimenko, were the two finalists for the New Frontiers program Mission 4,[25][26] and on 27 June 2019, NASA selected Dragonfly for development with a plan to launch in June 2027.[27][28]
On 3 March 2023, Dragonfly passed its preliminary design review (PDR).[29]
In November 2023 following
NASA's decision to postpone the formal confirmation of the mission due to funding uncertainties, the launch was delayed by one year, with a new launch date set for July 2028.[4]
Funding
The CAESAR and Dragonfly missions received US$4 million funding each through the end of 2018 to further develop and mature their concepts.[25] NASA announced the selection of Dragonfly on 27 June 2019, which is expected to be built and launched by July 2028.[4]Dragonfly is the fourth in NASA's New Frontiers portfolio, a series of principal investigator-led planetary science investigations that fall under a development cost cap of approximately US$850 million, and including launch services, the total cost projection is approximately US$1 billion.[30] A revised cost projection was released in April 2024, with Dragonfly now expected to incur a total lifecycle cost of US$3.35 billion due to supply chain increases and delays caused by the
COVID-19 pandemic.[31]
Science objectives
Titan is similar to the very early Earth, and can provide clues to how life may have arisen on
Earth. In 2005, the
European Space Agency's
Huygens lander acquired some atmospheric and surface measurements on Titan, detecting
tholins,[32] which are a mix of various types of hydrocarbons (
organic compounds) in the atmosphere and on the surface.[33][34] Because Titan's atmosphere obscures the surface at many wavelengths, the specific compositions of solid hydrocarbon materials on Titan's surface remain essentially unknown.[35] Measuring the compositions of materials in different geologic settings is intended to reveal how far prebiotic chemistry has progressed in environments that provide known key
ingredients for life, such as
pyrimidines (bases used to encode information in
DNA) and
amino acids, the building blocks of
proteins.[36]
Areas of particular interest are sites where
extraterrestrial liquid water in impact melt or potential
cryovolcanic flows may have interacted with the abundant organic compounds. Dragonfly would provide the capability to explore diverse locations to characterize the habitability of Titan's environment, investigate how far
prebiotic chemistry has progressed, and search for
biosignatures indicative of life based on water as solvent and even
hypothetical types of biochemistry.[6]
Dragonfly is designed as a
rotorcraft lander, much like a large
quadcopter with double rotors, which is known as an octocopter.[3] The rotor configuration provides redundancy to enable the mission to tolerate the loss of at least one rotor or motor.[3] Each of the craft's eight rotors is 1.35 m (4.4 ft) in diameter.[38][39] The aircraft would travel at about 10 m/s (36 km/h; 22 mph) and climb to an altitude of up to 4 km (13,000 ft).[3]
Flight on Titan is aerodynamically benign as Titan has low gravity and little wind, and its dense atmosphere allows for efficient rotor propulsion.[40] The
radioisotope thermoelectric generator (RTG) power source has been proven in multiple spacecraft, and the extensive use of quad drones on Earth provides a well-understood flight system that is being complemented with algorithms to enable independent actions in real-time.[40] The craft is designed to operate in a
space radiation environment and in temperatures averaging 94 K (−179.2 °C).[40]
Titan's dense atmosphere and low gravity mean that the flight power for a given mass is a factor of about 40 times lower than on Earth.[3] The atmosphere has 1.45 times the pressure and about four times the density of Earth's, and local gravity (13.8% of Earth's) makes flight easier than on Earth, although cold temperatures, lower light levels and higher atmospheric drag on the airframe will be challenges.[23]
Dragonfly should be able to fly several kilometers,[41] powered by a
lithium-ion battery, which is to be recharged by a
Multi-Mission Radioisotope Thermoelectric Generator (MMRTG) during the night.[21] MMRTGs convert the heat from the
natural decay of a
radioisotope into electricity.[3] Twenty-four
Radioisotope Heater Units (RHUs) are also kept reserved for this mission.[42] The rotorcraft should be able to travel ten miles (16 km) on each battery charge and stay aloft for a half hour each time.[43] The vehicle is to have sensors to scout new science targets, and then return to the original site until new landing destinations are approved by mission controllers.[43][44]
The Dragonfly rotorcraft will weigh approximately 450 kg (990 lb) and be packaged inside a heatshield of 3.7 m (12 ft) diameter.[3]Regolith samples are to be obtained by two sample acquisition drills and hoses, one on each landing skid, for delivery to the
mass spectrometer instrument.[3]
The craft is to remain on the ground during the Titan nights, which last about eight Earth days or 192 hours.[3] Activities during the night may include sample collection and analysis,
seismological studies like diagnosing wave activity on the northern hydrocarbon seas,[45]meteorological monitoring, and local microscopic imaging using
LED illuminators as flown on
Phoenix lander and
Curiosity rover.[3][46] The craft is designed to communicate directly to Earth with a
high-gain antenna.[3]
The
Penn State Vertical Lift Research Center of Excellence is responsible for rotor design and analysis, rotorcraft flight-control development, scaled rotorcraft testbed development, ground testing support, and flight performance assessment.[47]
Scientific payload
DraMS (Dragonfly Mass Spectrometer) is a
mass spectrometer to identify chemical components, especially those relevant to biological processes, in surface and atmospheric samples.[19]
DragonCam (Dragonfly Camera Suite) is a set of
microscopic and panoramic
cameras to image Titan's terrain and scout for scientifically interesting landing sites.[19]
In addition, Dragonfly is to have multiple engineering and monitoring instruments to determine characteristics of Titan's interior and atmosphere.[19]
Trajectory
Dragonfly is expected to launch in July 2028[48] and to take seven years to reach Titan, arriving by 2034.[49][1] The spacecraft is likely to perform a
gravity assist flyby of Earth to gain additional velocity on its way to Titan.[50] The spacecraft would be the first dedicated outer solar system mission to not visit Jupiter, as it will not be within the flight path.[51]
Entry and descent
The cruise stage is to separate from the entry capsule ten minutes before encountering Titan's atmosphere.[43] The lander would then descend to the surface of Titan using an
aeroshell and a series of two
parachutes, while the spent cruise stage would burn up in uncontrolled
atmospheric entry. The duration of the descent phase is expected to be 105minutes.[52] The aeroshell is derived from the Genesis sample return capsule, and the PICA heat shield is similar to
MSL and
Mars 2020 design and should protect the spacecraft for the first six minutes of its descent.[52]
At a speed of Mach 1.5, a
drogue parachute is to deploy, to slow the capsule to subsonic speeds. Due to Titan's comparatively thick atmosphere and low gravity, the drogue chute phase should last for 80 minutes.[52] A larger main parachute is to replace the drogue chute when the descent speed is sufficiently low. During the 20 minutes on the main chute, the lander is to be prepared for separation. The heat shield is to be jettisoned, the landing skids are to be extended, and sensors such as
radar and
lidar are to be activated.[52] At an altitude of 1.2 km (0.75 mi), the lander should be released from its parachute for a powered flight to the surface. The specific landing site and flight operation are to be performed autonomously. This is required since the
high gain antenna would not be deployed during descent, and because communication between Earth and Titan takes 70–90 minutes in each direction.[43]
Landing site
The Dragonfly rotorcraft should land initially in
dunes to the southeast of the Selk impact structure at the edge of the dark region called
Shangri-La.[54][5] It is planned to explore this region in a series of flights of up to 8 km (5.0 mi) each, and acquire samples from compelling areas with a diverse geography. After landing, it is planned to travel to the Selk impact crater, where in addition to
tholinorganic compounds, there is evidence of past liquid water.[5]
AVIATR – proposed airplane mission concept to Titan, a moon of SaturnPages displaying wikidata descriptions as a fallback – A mission concept of a Titan aircraft.
^
ab"OPAG August 2021"(PDF). Zibi Turtle, Dragonfly PI, JHUAPL. 31 August 2021.
Archived(PDF) from the original on 17 December 2023. Retrieved 22 January 2022. This article incorporates text from this source, which is in the
public domain.
^
abcdefghijklmnDragonfly: A Rotorcraft Lander Concept for Scientific Exploration at Titan Ralph D. Lorenz, Elizabeth P. Turtle, Jason W. Barnes, Melissa G. Trainer, Douglas S. Adams, Kenneth E. Hibbard, Colin Z. Sheldon, Kris Zacny, Patrick N. Peplowski, David J. Lawrence, Michael A. Ravine, Timothy G. McGee, Kristin S. Sotzen, Shannon M. MacKenzie, Jack W. Langelaan, Sven Schmitz, Larry S. Wolfarth, and Peter D. Bedini. 2018. Johns Hopkins APL Technical Digest, 34(3), 374-387
^Agle, DC; Johnson, Alana; Hautaluoma, Grey, eds. (19 February 2021).
"NASA's Mars Helicopter Reports In" (Press release).
JPL. 2021-036.
Archived from the original on 6 December 2023. Retrieved 20 February 2021. This article incorporates text from this source, which is in the
public domain.
^Maria E. McQuaide; Donald H. Ellison; Jacob A. Englander; Mark C. Jesick; Martin T. Ozimek; Duane C. Roth.
"Dragonfly Phase B Mission Design". researchgate.net. AAS 23-170 (reprint)
^[1] Selection and Characteristics of the Dragonfly Landing Site near Selk Crater, Titan Planetary Science Journal 2, 24 (2021)
doi:
10.3847/PSJ/abd08f
^
ab"Geology of the Selk crater region on Titan from Cassini VIMS observations" J.M. Soderblom, R.H. Brown, L.A. Soderblom, J.W. Barnes, R. Jaumann, Stéphane Le Mouélic, Christophe Sotin, K. Stephan, K.H. Baines, B.J. Buratti, R.N. Clark, and P.D. Nicholson; Icarus Volume 208, Issue 2, August 2010, Pages 905-912
doi:
10.1016/j.icarus.2010.03.001
^SelkGazetteer of Planetary Nomenclature Accessed on 29 June 2019
^"Crater topography on Titan: Implications for landscape evolution", C. D. Neish, R.L. Kirk, R. D. Lorenz, V. J. Bray, P. Schenk, B. W. Stiles, E. Turtle, K. Mitchell, A. Hayes, Icarus, 223 (2013)
doi:
10.1016/j.icarus.2012.11.030