Cluster Mission Poised for Spectacular Reentry Over the South Pacific

Cluster Satellite Reentering Earth’s Atmosphere
On September 8, 2024, ESA’s pioneering Cluster mission will come to a close as the first of its four satellites reenters Earth’s atmosphere, showcasing a historic and sustainable approach to space exploration.
Credit: ESA/David Ducross

ESA’s Cluster mission concludes on September 8, 2024, with the targeted reentry of its first satellite, setting a precedent in sustainable space exploration.

Over the course of 24 years, Cluster studied Earth’s magnetic shield, significantly advancing our understanding of space weather and its impacts.

Historic End of ESA’s Cluster Mission

On September 8, 2024, the first of four satellites that make up ESA’s Cluster mission will reenter Earth’s atmosphere over the South Pacific Ocean Uninhabited Area.

This marks the end of the historic mission, over 24 years after it was sent into space to measure Earth’s magnetic environment. Though the remaining three satellites will also stop making scientific observations, discoveries using existing mission data are expected for years to come.

This ‘targeted reentry’ is the first of its kind. ESA’s efforts to ensure a clean end to the Cluster mission go beyond international standards, making the agency a world leader in sustainable space exploration.

Cluster's Salsa Reentry
Infographic describes the reentry of the first of four Cluster satellites Credit: ESA

Space Safety Pioneer

Launched in 2000, Cluster has spent 24 years studying perhaps the one thing that makes Earth a unique habitable world where life can thrive: its powerful magnetic shield, the magnetosphere.

Like an enormous umbrella, the magnetosphere protects us from most of the driving rain of particles that the Sun relentlessly sends in our direction.

But gusts of this solar wind can still push through, sending bursts of energetic particles cascading towards Earth’s surface. The most common result is the northern and southern lights (auroras), but more rarely, these particles can cut our power supplies, disrupt radio communications, or damage satellites.

Space Weather Effects
Space weather refers to the environmental conditions in space as influenced by solar activity. Credit: ESA/Science Office

We call the influence of the solar wind on Earth’s magnetic environment ‘space weather’. And until Cluster came along, space weather remained something of a mystery.

“For over two decades, Cluster has shown us time and time again how important the magnetosphere is in shielding us from the solar wind,” says Cluster Mission Manager Philippe Escoubet. “It has watched the effects of solar storms to help us better understand and forecast space weather.”

A Zero-Debris Finale

Cluster was never designed to last this long, nor was it designed for such a safe finale. It was initially launched on a two-year mission to study the Sun–Earth interaction. Because it was carrying out such impressive and world-changing science, ESA’s spacecraft operators kept it going.

But all good things must come to an end, and Cluster’s time has finally come. With this targeted reentry, ESA is turning Cluster from a pioneer in space weather monitoring to a pioneer in mitigating space debris – two key elements in the agency’s space safety goals.

Without intervention, the four Cluster satellites would have reentered naturally in a less predictable manner, potentially over a more densely populated region. By targeting the satellites’ reentries, ESA is taking the opportunity to ensure that Cluster’s demise doesn’t contribute to the rocketing amount of space junk in orbit around Earth.

Cluster Reentry Ground Track
Map of Earth with a colored line overlaid that shows the path that Cluster will take over Earth’s surface on September 8, 2024. The line ends in the South Pacific Ocean, to the west of Chile. Credit: ESA

Salsa’s Last Dance

Of the four Cluster satellites – nicknamed Rumba (Cluster 1), Salsa (Cluster 2), Samba (Cluster 3) and Tango (Cluster 4) – Salsa will be the first to take the plunge back into Earth’s atmosphere. It is targeting a specific region of the South Pacific Ocean that is as far as possible from populated regions.

“Back in January we tweaked Salsa’s orbit to make sure that on September 8 it experiences its final steep drop from an altitude of roughly 110 km to 80 km,” explains Cluster Operations Manager Bruno Sousa. “This gives us the greatest possible control over where the spacecraft will be captured by the atmosphere and begin to burn up.”

Bruno’s team is now watching the satellite from a distance. A targeted reentry allows for so much predictability in the reentry time and location that there is no need for further maneuvers.

Cluster Mission
The Cluster mission comprises four satellites flying in a tetrahedral formation and collecting the most detailed data yet on small-scale changes in near-Earth space, and on the interaction between the charged particles of the solar wind and Earth’s magnetosphere. Credit: ESA

Studying Satellite Reentry Dynamics

Despite being confident that no surviving fragments will fall anywhere near land, we still have very little data about how spacecraft behave as they pass through the lower layers of the atmosphere. We would like to know more to predict even better the time and location of satellite reentries and ensure the safety of humans on Earth.

ESA is considering observing Salsa’s reentry from an aircraft; this will be confirmed later in August. The four Cluster satellites are identical and so by watching them reenter the atmosphere with slightly different trajectories and in different weather conditions, we would have the unique opportunity to conduct a valuable reentry experiment to study the break-up of satellites.

Role of Reentries Infographic
What goes up, nearly always comes back down. When it comes to the objects we send to space, atmospheric reentries are actually a fundamental tool in minimizing the creation of space debris and ensuring a sustainable future in space.
Objects in low-Earth orbit, affected by the ‘drag’ forces caused by Earth’s atmosphere, gradually lower in altitude and then make a rapid and fiery descent towards Earth.
Small objects disintegrate as they reenter due to the immense friction and heat created, but parts of larger bodies can reach the ground so should be controlled to land over uninhabited regions.
Join Stijn Lemmens and Jorge del Rio Vera to find out more about why this matters in the joint ESA-UN podcast that narrates this infographic. Credit: ESA / UNOOSA

Setting New Environmental Standards in Space

Cluster’s reentry follows those of ESA’s Aeolus and https://scitechdaily.com/a-fiery-farewell-to-esas-pioneering-ers-2-satellite/ERS-2 Earth observation missions. ESA is setting a precedent for a responsible approach to reducing the ever-increasing problem of space debris and uncontrolled reentries.

With this targeted reentry, ESA is again pioneering a new strategy to reduce its environmental impact by disposing of its missions more safely and sustainably than envisaged at the time of their design.

“By studying how Salsa burns up, which parts might survive, for how long and in what state, we will learn much about how to build ‘zero-debris’ satellites,” explains Tim Flohrer, Head of ESA’s Space Debris Office.

“The lessons learned from this activity will help turn targeted reentries into a safe and well-understood option for the disposal of other space missions in similar orbits, such as Smile and Proba-3.”

Future Directions and Legacy

Following Salsa’s reentry, the three remaining Cluster satellites will enter ‘caretaker’ mode; while they will not be making scientific measurements, operators will be monitoring them to minimize the risk of collision with other satellites or Earth itself.

Bruno’s team will adjust the orbit of Rumba (Cluster 1) in August 2024 in preparation for a similar targeted reentry in November 2025. They will then maneuver Samba (Cluster 3) and Tango (Cluster 4) in November 2024 ready for Cluster’s final goodbye in August 2026.

At the end of 2025, ESA plans to launch its next mission to tackle Earth’s magnetic environment: the Solar wind Magnetosphere Ionosphere Link Explorer, or Smile for short. A joint venture with the Chinese Academy of Sciences, Smile will build upon Cluster to reveal even more about the complex and intriguing magnetic environment surrounding planet Earth.