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NASA’s Lucy mission, launched on October 16, 2021, is the first space mission specifically designed to study the Trojan asteroids, a unique group of asteroids that orbit the Sun in two large swarms around Jupiter—one leading and one trailing the gas giant. These celestial bodies are believed to be remnants from the early solar system, offering valuable clues about the formation of the planets. Named after the fossilized human ancestor “Lucy,” whose discovery shed light on human evolution, this spacecraft similarly seeks to uncover the ancient history of the solar system.

The Lucy mission has four primary scientific goals:

Surface Geology – Analyze surface features to determine the history of cratering, layering, and possible past activity like volcanism.

Surface Composition – Identify the composition of the asteroids’ surfaces to infer the origins of their materials.

Interior and Bulk Properties – Measure mass, density, and structure of each asteroid to understand their internal makeup.

Satellites and Rings – Search for small moons and ring systems, which may help scientists understand how Trojan asteroids have evolved.

By studying these diverse objects, Lucy is expected to provide insights into planetary formation processes and the dynamics of the early solar system.

Lucy’s mission trajectory is one of the most complex ever attempted. It involves multiple gravity assists and a looping journey through the inner solar system to reach different groups of Trojan asteroids. After launching from Cape Canaveral aboard an Atlas V rocket, Lucy began a 12-year journey involving three Earth gravity assists:

First Earth flyby: October 2022

Second Earth flyby: December 2024

Third Earth flyby: December 2030

These assists help shape Lucy’s path to visit eight asteroids in total—a record for a single NASA mission. These include:

Donaldjohanson (Main Belt asteroid, 2025) – Named after the discoverer of the Lucy hominid fossil.

Eurybates and its satellite Queta (leading Trojan swarm, 2027)

Polymele (2027)

Leucus (2028)

Orus (2028)

Patroclus and Menoetius (binary pair in the trailing Trojan swarm, 2033)

The spacecraft’s ability to fly by both leading and trailing Trojan camps is made possible by its unique and precisely calculated orbit, using Earth’s gravity to slingshot itself across vast distances.

To fulfill its objectives, Lucy is equipped with a suite of three main science instruments:

L’LORRI (Lucy LOng Range Reconnaissance Imager): A high-resolution telescopic camera designed to capture detailed images of the surface features of the Trojan asteroids, similar to what New Horizons used for Pluto.

L’Ralph: This instrument includes both a color visible camera and an infrared spectrometer to analyze surface composition and detect ices, organics, and minerals.

L’TES (Lucy Thermal Emission Spectrometer): Measures the heat emitted from asteroid surfaces, helping scientists estimate the texture and composition of the materials.

In addition to these, Lucy uses a high-gain antenna and radio tracking to precisely measure the gravitational tug of the asteroids during flybys—key for calculating mass and internal structure.

The mission timeline is as follows:

Launch: October 16, 2021

Earth Flyby 1: October 2022 (completed successfully)

Main Belt asteroid Donaldjohanson flyby: April 2025

Trojan flybys (Eurybates, Queta, Polymele, Leucus, Orus): 2027–2028

Return to Earth for gravity assist: December 2030

Patroclus and Menoetius (binary system) flyby: March 2033

End of Primary Mission: Late 2033 (though the spacecraft may continue as an extended mission platform depending on health and power)

NASA’s Lucy mission is a bold and pioneering effort to study some of the oldest and most distant relics of our solar system. Through its ambitious trajectory and carefully selected instruments, Lucy will give scientists an unprecedented look into the origins and evolution of our planetary neighborhood. By exploring a diverse array of Trojan asteroids—each with its own unique story—Lucy stands to revolutionize our understanding of how the planets formed and why our solar system looks the way it does today.

Video credit: NASA Goddard