NASA unveils a groundbreaking approach to bring Martian rock samples back to Earth by 2026, introducing competition between two strategic plans to enhance cost-efficiency and spark innovation.
These Martian samples could revolutionize our understanding of Mars and the wider universe, potentially altering our perception of life’s origins and evolution
NASA’s Dual Path Strategy for Mars Sample Return
NASA has unveiled a new approach to its Mars Sample Return Program to increase the chances of successfully bringing the first Martian rock and sediment samples to Earth. The agency will explore two different landing strategies simultaneously during the program’s development phase. This dual-track approach is designed to foster competition, spark innovation, and reduce costs and timelines.
Ultimately, NASA will choose one strategy to move forward with, as the program aims to unlock the mysteries of the universe and investigate whether Mars ever supported life. The final design and confirmation of the program are expected in the latter half of 2026.
Enhancing Cost Efficiency and Scientific Potential
“Pursuing two potential paths forward will ensure that NASA is able to bring these samples back from Mars with significant cost and schedule saving compared to the previous plan,” said NASA Administrator Bill Nelson. “These samples have the potential to change the way we understand Mars, our universe, and – ultimately – ourselves. I’d like to thank the team at NASA and the strategic review team, led by Dr. Maria Zuber, for their work.”
In September 2024, the agency accepted 11 studies from the NASA community and industry on how best to return Martian samples to Earth. A Mars Sample Return Strategic Review team was charged with assessing the studies and then recommending a primary architecture for the campaign, including associated cost and schedule estimates.
Expediting Martian Science
“NASA’s rovers are enduring Mars’ harsh environment to collect ground-breaking science samples,” said Nicky Fox, who leads NASA’s Science Mission Directorate. “We want to bring those back as quickly as possible to study them in state-of-the-art facilities. Mars Sample Return will allow scientists to understand the planet’s geological history and the evolution of climate on this barren planet where life may have existed in the past and shed light on the early solar system before life began here on Earth. This will also prepare us to safely send the first human explorers to Mars.”
During formulation, NASA will proceed with exploring and evaluating two distinct means of landing the payload platform on Mars. The first option will leverage previously flown entry, descent, and landing system designs, namely the sky crane method, demonstrated with the Curiosity and Perseverance missions. The second option will capitalize on using new commercial capabilities to deliver the lander payload to the surface of Mars.
Technological Innovations and Strategic Partnerships
For both potential options, the mission’s landed platform will carry a smaller version of the Mars Ascent Vehicle. The platform’s solar panels will be replaced with a radioisotope power system that can provide power and heat through the dust storm season at Mars, allowing for reduced complexity.
The orbiting sample container will hold 30 of the sample tubes containing samples the Perseverance lander has been collecting from the surface of Mars. A redesign of the sample loading system on the lander, which will place the samples into the orbiting sample container, simplifies the backward planetary protection implementation by eliminating the accumulation of dust on the outside of the sample container.
Both mission options rely on a capture, containment, and return system aboard ESA’s (European Space Agency’s) Earth Return Orbiter to capture the orbiting sample container in Mars orbit. ESA is evaluating NASA’s plan.
