BY:SpaceEyeNews.
A Quiet But Powerful Achievement in Orbit
In one of the most significant yet understated breakthroughs in modern space operations, China has reportedly completed the world’s first satellite-to-satellite refueling mission in geostationary orbit (GEO)—a feat that could permanently reshape how we think about satellite lifespans and orbital sustainability.
Operating at 36,000 kilometers above Earth, this orbital test involved two Chinese satellites: Shijian-21 (SJ-21) and Shijian-25 (SJ-25). Over a span of a few days in early June 2025, analysts from leading space situational awareness firms tracked SJ-25 as it approached and docked with SJ-21. What followed, according to credible sources, was a successful transfer of approximately 142 kilograms of hydrazine fuel from SJ-25 to SJ-21.
The result? An extension of SJ-21’s operational life by up to eight years, making this not just a technical milestone, but a paradigm shift in satellite operations.
How the Refueling Was Detected
The maneuver wasn’t publicly announced. Instead, it was uncovered by persistent observation from private tracking companies, including Slingshot Aerospace and COMSPOC (Commercial Space Operations Center). These companies monitor global satellite movements and anomalies using a network of ground-based sensors and AI-powered tracking systems.
On June 9, 2025, SJ-25 and SJ-21 began closing their relative orbital distance. The satellites reduced their separation to just under two degrees of longitude, which in GEO translates to only a few hundred kilometers—a clear sign that a rendezvous was in motion.
By June 11, orbital behavior indicated that the two spacecraft had matched velocities and begun coordinated movement—suggestive of docking or synchronized operations. Slingshot analysts flagged this behavior as consistent with in-orbit servicing, and follow-up data strongly supported a hydrazine fuel transfer between the satellites.
The information was further corroborated by two U.S. military satellites—USA 270 and USA 271—which were observed repositioning themselves to monitor the event. Both are part of the Geosynchronous Space Situational Awareness Program (GSSAP), a system designed to track high-value activities in GEO. Their movements lent additional credibility to the refueling claim, even without direct confirmation from Chinese officials.
The Satellites Involved: SJ-21 and SJ-25
The two spacecraft involved are part of China’s Shijian series—a line of experimental satellites typically launched for advanced technology demonstrations. Their names translate roughly to “Practice” or “Experiment,” hinting at their role in trialing future-focused space capabilities.
Shijian-21 (SJ-21) was launched in October 2021 and previously drew international attention for its maneuverability. In 2022, SJ-21 successfully docked with a defunct satellite—Beidou-2 G2, a retired member of China’s navigation constellation—and towed it to a higher, non-operational “graveyard orbit.” That event demonstrated its ability to perform precise docking, positioning it as a potential space servicing or debris mitigation satellite.
Shijian-25 (SJ-25), launched in January 2025, was publicly described by Chinese sources as designed for on-orbit refueling demonstrations. Its arrival in GEO, proximity maneuvers, and the eventual synchronized activity with SJ-21 align with its stated purpose. Observers have now concluded with high confidence that it acted as a fuel depot, transferring hydrazine to its counterpart.
This is the first time such an operation has been tracked in geostationary orbit, making it a world-first demonstration of orbital refueling at such extreme altitude—where satellites typically cost hundreds of millions of dollars and are extremely difficult to replace.
Why GEO Refueling Is a Big Deal
Geostationary orbit is unlike other orbital zones. At 36,000 kilometers from Earth, satellites in GEO maintain a fixed position relative to the surface, making them vital for communications, weather forecasting, global broadcasting, and defense infrastructure. However, satellites in this orbit have always had one major weakness: limited onboard fuel.
Once a satellite runs out of fuel—typically hydrazine or xenon—it can no longer maintain its orbital slot or adjust its position. Even if its electronics and payload are fully functional, it must be decommissioned or moved to a graveyard orbit.
That’s what makes China’s refueling maneuver so significant. By demonstrating in-orbit servicing in GEO, they’ve opened the door to extending satellite lifespans by years or even decades, saving billions in hardware replacement and launch costs.
According to COMSPOC’s analysis, the 142 kg hydrazine transfer to SJ-21 could extend its mission life by up to eight years. That’s nearly double the average operational period for many GEO satellites. It also delays the need for new launches, reduces orbital debris, and paves the way for long-term satellite maintenance strategies.
The ability to service satellites after deployment radically shifts how satellite infrastructure will be designed going forward—less disposable, more sustainable.
What Makes This Technologically Challenging
Unlike robotic refueling efforts in low Earth orbit (LEO), servicing in GEO introduces unique engineering and navigational hurdles. At such high altitudes, gravitational forces are weaker, but orbital speeds remain high—meaning satellites must match velocity with incredible precision.
To transfer fuel in space, two satellites must dock or come into extremely close alignment, connect a fuel line without leaks, and synchronize their onboard systems to control pressure and flow rate. Any error could destabilize the orbit or damage both spacecraft.
This is why even the most advanced space agencies, including NASA and ESA, have struggled to demonstrate GEO servicing missions beyond the experimental stage. While NASA’s Restore-L project aims to service LEO satellites and DARPA’s RSGS is still in development, no Western nation has yet proven this capability in GEO with live satellites.
China’s quiet demonstration suggests they’ve cleared a major technical hurdle that others are still preparing to attempt.
A New Model for Space Infrastructure
What we’re witnessing is a shift away from single-use space assets toward modular, serviceable systems. China’s success shows that satellites can be built not just for short-term missions, but for ongoing performance with periodic support.
This mirrors how we manage infrastructure on Earth: aircraft undergo mid-life maintenance, electric grids are upgraded, and ships are refitted. Now, satellites may join this club of maintainable, upgradable platforms.
This achievement may also lead to new satellite design standards, such as standardized fuel ports, replaceable components, and cooperative servicing interfaces. In the future, fleets of “helper” satellites like SJ-25 could be deployed to support entire constellations in orbit.
It also improves orbital safety. Well-maintained satellites are less likely to drift, malfunction, or become uncontrollable space debris—an increasingly serious issue in both GEO and LEO.
What Comes Next?
This isn’t just a one-off win for China—it’s a signal of where global space operations are headed. In-orbit logistics is becoming a new focus for national space agencies and private companies alike. The ability to service, refuel, and maneuver satellites post-launch adds resilience and flexibility to any orbital strategy.
We can expect to see increased investment in space infrastructure that supports long-duration, modular missions. Future systems may include orbital fuel depots, robotic repair arms, autonomous service vehicles, and even satellite recycling technologies.
As other nations react, we may also see a push for international guidelines on orbital servicing, safety, and cooperation. The ability to approach, dock with, or manipulate another satellite is sensitive by nature and must be governed carefully to prevent misinterpretations or accidents.
But if done collaboratively, this technology could lead to a future where space is not only accessible—but sustainable, serviceable, and shared.
Conclusion: A Turning Point Above Earth
With almost no public attention, China has reportedly changed the rules of the game. By refueling a satellite in geostationary orbit, it has introduced a new chapter in orbital capability—one focused not just on reaching space, but on staying there, maintaining presence, and optimizing assets.
This success sets a new standard in global space operations and raises the bar for what’s possible in the most valuable orbital territory surrounding our planet. As space becomes increasingly central to communication, science, and exploration, one thing is clear: the future will belong not just to those who launch—but to those who can sustain, service, and adapt.
Stay tuned to SpaceEyeNews for ongoing coverage as we continue tracking this major shift in orbital strategy and the race toward truly sustainable space operations.
References:
https://interestingengineering.com/space/china-to-perform-critical-satellite-refueling