Lucy is aNASAspace probe on a twelve-year journey to eight differentasteroids. It is slated to visit twomain belt asteroids as well as sixJupiter trojans – asteroids that shareJupiter's orbit around the Sun, orbiting either ahead of or behind the planet.[4][5] All target encounters will beflyby encounters.[6]
TheLucy spacecraft is the centerpiece of a US$981 million mission.[7] On 4 January 2017,Lucy was chosen, along with thePsyche mission, as NASA'sDiscovery Program missions 13 and 14 respectively.[6][8] It was launched on 16 October 2021. In November 2023[9] and in April 2025[10][11] it flew by and photographed asteroidsDinkinesh andDonaldjohanson, respectively. Lucy will reach its first main target, the Jupiter Trojan asteroidEurybates, in August 2027.
The mission is named after theLucy hominin fossils, because study of the trojans could reveal the "fossils of planet formation": materials that clumped together in the early history of theSolar System to form planets and other bodies.[12] The hominid was named after the 1967Beatles song "Lucy in the Sky with Diamonds".[13] The spacecraft carries a disc made of lab-grown diamonds for itsL'TES instrument.[14]
Lucy was launched fromCape Canaveral SLC-41 on 16 October 2021, at 09:34UTC[3] on the 401 variant of aUnited Launch AllianceAtlas V launch vehicle. It gained onegravity assist from Earth a year later on 16 October 2022,[15] and after making a flyby of the asteroid152830 Dinkinesh in 2023,[16] gained another gravity assist from Earth in 2024.[17] In 2025, it flew by the inner main-belt asteroid52246 Donaldjohanson, which was named after the discoverer of the Lucy hominin fossil.[18] In 2027, it will arrive at theL4 Trojan cloud (theGreek camp of asteroids that orbits about 60° ahead of Jupiter), where it will fly by four Trojans,3548 Eurybates (with its satellite),15094 Polymele,11351 Leucus, and21900 Orus.[6] After these flybys,Lucy will return to Earth in 2031 for another gravity assist toward theL5 Trojan cloud (theTrojan camp which trails about 60° behind Jupiter), where it will visit thebinary Trojan617 Patroclus with itssatelliteMenoetius in 2033. The mission may end with the Patroclus–Menoetius flyby, but at that pointLucy will be in a stable, 6-year orbit between the L4 and L5 clouds, and a mission extension will be possible.[19]
Exploration of Jupiter Trojans is one of the high-priority goals outlined in thePlanetary Science Decadal Survey. Jupiter Trojans have been observed by ground-based telescopes and theWide-field Infrared Survey Explorer to be "dark with... surfaces that reflect little sunlight".[21] Jupiter is 5.2 AU (780×10^6 km; 480×10^6 mi) from the Sun, or about five times the Earth-Sun distance.[22] The Jupiter Trojans are at a similar distance but can be somewhat farther or closer to the Sun depending on where they are in their orbits. There may be as many Trojans as there areMain-belt asteroids.[23]
NASA selectedLucy through the Discovery ProgramAnnouncement of Opportunity (AO) released on 5 November 2014.[24]Lucy was submitted as part of a call for proposals for the next mission(s) forDiscovery Program that closed in February 2015. Proposals had to be ready to launch by the end of 2021. Twenty-eight proposals were received in all.
On 30 September 2015,Lucy was selected as one of five finalist missions, each of which received US$3 million to produce more in-depth concept design studies and analyses.[25][26][27][28] Its fellow finalists wereDAVINCI,NEOCam,Psyche andVERITAS. On 4 January 2017,Lucy andPsyche were selected for development and launch.
On 31 January 2019, NASA announced thatLucy would launch in October 2021 on anAtlas V 401 launch vehicle fromCape Canaveral,Florida. The total cost for the launch was estimated to be US$148.3 million.[29] On 11 February 2019,SpaceX protested the contract award, claiming that it could launchLucy into the same orbit at a "significantly cheaper cost". On 4 April 2019, SpaceX withdrew the protest.[30]
On 28 August 2020, NASA announced thatLucy had passed its Key Decision Point-D (KDP-D) with a "green light" to assemble and test the spacecraft and its instruments.[31] The spacecraft instruments arrived beginning with L'LORRI on 26 October 2020.[32] On 30 July 2021, the spacecraft was transported on aC-17 transport aircraft to Florida for launch preparations, andLucy was encapsulated into the rocket fairing on 30 September 2021.
Lucy was launched on 16 October 2021 at 09:34UTC[33][34] at the opening of its 23-day launch window.[34]
L'Ralph – panchromatic and color visible imager (0.4–0.85μm) and infrared spectroscopic mapper (1–3.6μm). L'Ralph is based on theRalph instrument onNew Horizons and was built atGoddard Space Flight Center. It will be used to measure silicates, ices, and organics at the surface. The L'Ralph instrument has a three-mirror anastigmat design f/6 with a 75mm aperture. The telescope structure is composed from one aluminum block to provide an athermal imaging system. A beamsplitter transmits the longer wavelength light to LEISA and reflects light short of ~960nm to MVIC. The instrument is passively cooled with a 20-inch (510 mm) diameter radiator that cools the LEISA detector to ~100K. A new component of the L'Ralph instrument compared with its predecessors is a scan mirror assembly. The scan mirror is used to sweep the target across the Ralph focal planes to build up either visible images or infrared spectra.[35]
CAD drawing of the L'LORRI
L'LORRI – high-resolution visible imager. L'LORRI is derived from theLORRI instrument onNew Horizons and was built at theJohns Hopkins UniversityApplied Physics Laboratory. It will provide the most detailed images of the surface of the Trojans. L'LORRI uses the same detector and has the same optical design asNew Horizons LORRI. The primary mirror has a diameter of 20.8cm, the system has a focal length of 262cm, and the detector is a 1024 × 1024 thinned back-illuminated frame transfer CCD from Teledyne e2v. Each pixel subtends 5μrad (1.03arcseconds) and will have a point-spread function with a FWHM of less than 15μrad (<3.09arcseconds). Differences from the heritage instrument worth noting are the addition of redundant electronics, memory to store LORRI data, and the difference in the instrument accommodation. OnNew Horizons, the LORRI instrument is inside of the spacecraft, but onLucy L'LORRI is mounted on an Instrument Pointing Platform (IPP).[35]
L'TES
L'TES – thermal infrared spectrometer (6–75μm). L'TES is similar to OTES on theOSIRIS-REx mission and was built atArizona State University. It will reveal the thermal characteristics of the observed Trojans, which will also inform the composition and structure of the material on the surface of the asteroids. OTES was used to derive the surface composition and thermal inertia of the asteroid Bennu. However, because the Trojan asteroids at 5AU are much colder than Bennu, theLucy mission does not plan to use L'TES to derive surface composition. Instead, L'TES will be used primarily to infer regolith properties. L'TES has the same optical–mechanical design as OTES, including a 15.2cm diameter Cassegrain telescope, a Michelson interferometer with chemical vapor deposited diamond beamsplitter, and an uncooled, deuterated L-alanine doped triglycine sulfate (DLATGS) pyroelectric detector. L'TES has only small differences from the heritage instrument including removing a potential stray light path by modifying the telescope baffle and primary mirror inner diameter and improvements to the metrology laser system. An internal calibration cone blackbody target provides radiometric calibration. The L'TES instrument collects data from 6–75μm and has a noise equivalent spectral radiance (NESR) of 2.310–8Wcm−2sr−1cm−1 between 300cm−1 (7.4μm) and 1350cm−1 (33μm). For surfaces with temperatures greater than 75K, L'TES will determine the temperature with an accuracy of 2K. The 50% encircled energy of the instrument subtends 6.5 mrad. L'TES has one mode of taking data. It continuously collects interferograms (every 0.5, 1.0, or 2.0s) and transfers them to the spacecraft for storage before downlink. The instrument will start collecting data one day before closest approach, which is before the target fills the instrument's FOV. The data collection will continue until one day after closest approach. The L'TES instrument will measure the radiance of each Trojan asteroid at four locations at different local times of day with the additional requirement that one observation measures a location within 30° of the subsolar point and another measures the unilluminated surface.[35]
The radio science investigation will determine the mass of the Trojans by using the spacecraft radio telecommunications hardware andhigh-gain antenna to measureDoppler shifts.
T2CAM – terminal tracking camera (T2CAM or TTCAM) would be used to take wide-field images of the asteroids to better constrain the asteroids shapes.
Illustration of the deployed spacecraft
Lucy spacecraft solar arrays deploying and main engine burn
A plaque on theLucy mission featuring 20 messages from people on Earth
On board the spacecraft is a golden plaque that contains its launch date, the positions of the planets at the launch date, the continents of Earth at the time of launch, its nominal trajectory, and twenty speeches, poems, and song lyrics from people such asMartin Luther King Jr.,Carl Sagan,The Beatles, and more. Because the spacecraft will not leave theSolar System or be intentionally crashed into a planetary body, there is a chance that future generations of humanity will be able to recover it.[36]
Lucy will alternate visiting Jupiter'sGreek (L4) andTrojan camps (L5) every six years.Seven of theLucy mission's targets: the binary asteroid Patroclus/Menoetius, Eurybates, Orus, Leucus, Polymele, and the main belt asteroid Donaldjohanson.
Lucy's trajectory was designed to visit as many and various asteroids as the maneuvering budget allows.[37] The main elements of the trajectory are an Earth flyby, observation of asteroid Dinkintesh, a large deep space maneuver, another Earth flyby, then past asteroid Donaldjohnson on the way to 4 asteroids (2 double) at Jupiter's L4. Then the orbit falls back to Earth for another flyby, then on to Jupiter's L5. The first flyby was not strictly needed - the same rocket could put Lucy onto the post-encounter trajectory a year later, and result in exactly the same tour. But it provided schedule margin (which was not needed) and a practice flyby of Earth. However, the deep space maneuvers, and the resulting second Earth flyby, were required[38] to add the additional velocity needed to reach Jupiter's orbit. So far, as of May 2025, the first two Earth flybys, the first two asteroid encounters, and the deep space maneuver[39] have all completed as scheduled.
The specific objects that are targeted forflyby observation passes performed by the spacecraft include:[18][40][41][42]
Lucy Rollout and Lift & MateThe launch on 16 October 2021 at 5:34 am EDT
Although theLucy concept originated in late 2014, and was selected for funding in 2015, theLucy spaceflight began on 16 October 2021 with the launch of the Lucy spacecraft aboard aUnited Launch AllianceAtlas V 401 launch vehicle[55] into a stableparking orbit. During the next hour, the second stage reignited to placeLucy on aninterplanetary trajectory in aheliocentric orbit on a twelve-year mission to two groups of Sun-JupiterTrojan asteroids as well as close flybys of main belt asteroids during one of three planned passes through theasteroid belt. If the spacecraft remains operational during the 12-year planned duration, it is likely the mission will be extended and directed to additional asteroid targets.[56][57]
On 16 October 2021Lucy began to unfurl its two solar arrays. While the initial deployment of the arrays appeared to go smoothly, it was later discovered that one of the solar arrays failed to latch securely into open position.Thomas Zurbuchen, NASA's associate administrator for science, stressed the spacecraft remained "safe and stable".[58] Later testing on 26 October indicated the affected array was between 75 and 95 percent of full deployment. As of January 2022[update], the spacecraft is in cruise mode. NASA has stated they are reviewing a range of potential options, including simply letting the array remain as it is.[59][60] In late January 2022 NASA announced that they had found the cause for the failure of one of the solar arrays to fully deploy and then latch open securely. At the time, the agency's view was that there were two options to proceed: try to redeploy the solar array by further running of the array deployment motor, or leave the array as is, i.e. make no further attempt to fully open and latch it. Even with one solar array only partially deployed, the spacecraft was generating enough power for the mission. NASA said it would consider thoroughly its options and only take action at a (much) later time, as the issue was not an imminent risk to the mission.[61]
On 9 May 2022Lucy executed its first step in completing the deployment of the unlatched solar array. This was not intended to fully deploy and latch the array but simply to validate that the team's ground testing adequately represented the array-latch problem. After reviewing the data, the next planned step was for another deployment effort.[62][63]
By 5 August 2022, NASA reported that solar array is between 353 degrees and 357 degrees open (out of 360 degrees) but not latched, making it stable enough for the spacecraft to operate as needed for mission operations.[64][65]
After an intervention attempt on 13 December 2022, the team suspended further work with the solar panels.[66]
Dinkinesh and its satellite Selam imaged by theLucy spacecraft's L'LORRI camera, one minute before closest approach at a distance of 430 km (270 mi)
On 25 January 2023 NASA announced thatLucy would fly by the main-belt asteroid152830 Dinkinesh, which was previously overlooked as a potential target because the asteroid was too small.[67]Lucy's original trajectory took it within 64,000 km (40,000 mi) of the asteroid, but a series of maneuvers from May to September 2023 moved the spacecraft's trajectory closer to the asteroid.[68]
On 1 November 2023,Lucy successfully flew by its first target, 152830 Dinkinesh, at a relative speed of 4.5 km/s (2.8 mi/s).[69] On the following day, NASA released images from the flyby and announced the discovery of a small satellite orbiting Dinkinesh.[70] The first images from the flyby showed that Dinkinesh is approximately 790 m (2,590 ft) in diameter, while the satellite is approximately 220 m (720 ft) in diameter.[71] Later images showed that the satellite was actually two objects in direct contact, known as acontact binary.[72] The discovery of Dinkinesh's satellite brought the total number ofLucy's planned asteroid visits up to eleven.
The asteroid Donaldjohanson as seen by theLucy 's Long-Range Reconnaissance Imager (L’LORRI) during its flyby
Lucy first imaged52246 Donaldjohanson on 25 February 2025, at a distance of 70 million kilometres (43 million miles).[73]
On 20 April 2025, the spacecraft successfully flew by Donaldjohanson at a distance of 960 kilometres (600 mi) and a speed of more than 30,000 mph.[74][75] The flyby, which was considered a "dress rehearsal" for Lucy's encounters with Trojan asteroids closer to Jupiter, involved Lucy autonomously tracking Donaldjohanson with its antenna facing away from Earth, precluding communications. Forty seconds before closest approach, Lucy stopped tracking Donaldjohanson to shield the spacecraft's instruments from the sun.[73] The first set of images released the next day revealed that Donaldjohanson was acontact binary and larger than first predicted; at approximately 8 kilometres (5.0 mi) long and 3.5 kilometres (2.2 mi) wide at its widest point.[74]
Lucy captured a series of photos between September 15–17, 2025 of3I/ATLAS using high-resolution, black-and-white imager, L’LORRI, as the comet was zooming toward Mars. Lucy was 240 million miles away from 3I/ATLAS at the time.[76]
^Wall, Jennifer (1 June 2015)."What Is Jupiter?". NASA.Archived from the original on 19 July 2015. Retrieved16 October 2015. This article incorporates text from this source, which is in thepublic domain.
^Noll, K. S.; Grundy, W. M.; Buie, M. W.; Levison, H. F.; Olkin, C.; Marchi, S.; Brown, M. E.; Mottola, S. (22 August 2018),15622 – Confirmation of a Binary Companion to 21900 Orus(PDF), Space Telescope Science Institute,archived(PDF) from the original on 16 February 2022, retrieved7 June 2019
^"Lucy Mission". NASA. 30 April 2021.Archived from the original on 7 June 2021. Retrieved15 October 2021. This article incorporates text from this source, which is in thepublic domain.
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).
.jpg)
_(cropped).jpg)
This article incorporates text from this source, which is in thepublic domain.
Material was copied from this source, which is available under aCreative Commons Attribution 4.0 International LicenseArchived 16 October 2017 at theWayback Machine
.png)
