Astrobotic fires next-generation 'rotating detonation rocket engine' in record-breaking test (video)
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An account already exists for this email address, please log in. Subscribe to our newsletterPittsburgh-based Astrobotic has completed a successful series of hot-fire tests of its rotating detonation rocket engine prototype Chakram, marking a key milestone toward bringing the experimental propulsion technology to flight readiness.
Rotating detonation rocket engines (RDREs) work differently from conventional designs. Typical rocket engines rely on a steady, controlled process of chemical propellant ignition inside a combustion chamber. RDREs use a continuous, circular detonation wave that travels around a ring-shaped chamber, which produces higher pressure and efficiency and results in increased thrust with less fuel. In theory, that can improve efficiency by around 10–15%, while also reducing engine size and weight — advantages that are especially important for spacecraft, where every ounce of weight needs to be accounted for. But the benefits have been difficult to realize in practice.
Astrobotic, however, thinks the tests of its new RDRE prototype could help finally bring this type of propulsion into deep space, including around the moon. “Chakram more than exceeded our expectations,“ said Bryant Avalos, Astrobotic’s Principal Investigator for Chakram.
"Demonstrations like this show how RDRE technology could support a wide range of Astrobotic missions, from propulsion on future lunar landers to in-space orbital transfer vehicles, and other capabilities that will help expand operations throughout cislunar space.”
The campaign took place at NASA’s Marshall Space Flight Center (MSFC) in Huntsville, Alabama, and used two rotating detonation rocket engine (RDRE) prototypes for long-duration burns that suggest the engine can operate continuously, not just in short, proof-of-concept bursts.
Together, the two Chakram engines accumulated more than 470 seconds of firing time across multiple ignitions, and, in one test, burned continuously for 300 seconds. Astrobotic says that duration is likely the longest sustained firing of a rotating detonation engine to date, and the hardware showed no visible signs of damage afterward.
That kind of performance begins to address one of the biggest open questions around RDREs, and whether the engine design can operate reliably enough for use on actual spacecraft.
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During testing, each Chakram RDRE produced more than 4,000 pounds of thrust, and reached stable, "thermal steady state" conditions, according to an Astrobotic release — indicative of nominal, sustained engine operation. That combination of thrust, stability, and durability marks a meaningful step beyond earlier RDRE demonstrations, which have often been limited in duration.
“The 300-second burn was the cherry on top,“ Avalos said.
Chakram is a significant addition to Astrobotic's portfolio, and the company is developing Chakram with future missions in mind. Chakram could eventually be used on later versions of its Griffin lunar lander, as well as on planned reusable rockets and an orbital transfer vehicle designed for cislunar operations, according to Astrobotic's release.
Work on the Chakram RDRE has been supported through NASA Small Business Innovation Research (SBIR) contracts and a Space Act Agreement with MSFC. Part of that effort has focused on injector design and advanced manufacturing, including "tunable porosity metal additive manufacturing" — a 3D printing technique that aims to improve thermal management and combustion stability.
The data from this campaign is expected to guide improvements in engine throttling, regenerative cooling, and reducing overall mass as Astrobotic works to transition the engine from testing to flight-ready hardware.
Controlling and maintaining a stable detonation wave over long periods has been a persistent challenge, with many early tests limited to short bursts or unstable operation, but Astrobotic isn't the first company to take on the challenge.
Venus Aerospace completed an RDRE test flight last year using their own design, and marked the first successful test of such an engine from the U.S.

Josh Dinner is Space.com's Spaceflight Staff Writer. He is a writer and photographer with a passion for science and space exploration, and has been working the space beat since 2016. Josh has covered the evolution of NASA's commercial spaceflight partnerships and crewed missions from the Space Coast, NASA science missions and more. He also enjoys building 1:144-scale model rockets and spacecraft. Find some of Josh's launch photography on Instagram, and follow him on X, where he mostly posts in haiku.
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