Signs of ancient life may have been found in Martian rock – new study

According to Nature, the Perseverance rover's Cheyava Falls rock carries organic matter and iron-sulphide minerals that may reflect ancient life-like redox chemistry. The Nature paper notes that a definitive verdict requires bringing the sample back to Earth for thorough laboratory analysis, and that NASA's Mars Sample Return program faces budget and scheduling hurdles. While not conclusive, the findings bolster the case that Mars once hosted environments capable of supporting life and highlight why future sample return could provide the decisive evidence scientists seek.

Just over a year ago, Nasa made a remarkable announcement. The Perseverance rover had found potential signs of ancient life on Mars. Now, the technical details behind that discovery have been published in a Nature paper that, despite its rather modest wording, may ultimately prove to be among the most significant in the history of science.

The bottom line is this: it might be life, but we won’t know for sure until we return the samples to Earth. Perseverance has already collected a fragment of the relevant rock — we just have to go and get it.

Indeed, Nasa has been working with the European Space Agency on a mission to go to Mars, retrieve the samples of rock collected by Perseverance and deliver them to Earth. This would include the sample from the rock that’s the subject of the Nature study. However, the mission, known as Mars Sample Return, has run into trouble because of rising costs.

In mid-2024, the Perseverance rover encountered a block of ancient mudstone, nicknamed Cheyava Falls, distinguished by its brick-red hue. This rock was laid down by water roughly four billion years ago. While most Martian rocks appear red due to a coating of oxidised (ferric) iron dust, Cheyava Falls is red through and through – the ferric iron is in the rock itself.

More intriguingly, Cheyava Falls is peppered with dozens of tiny pale spots, typically less than a millimetre across. These spots are fringed with a dark phosphorus-rich mineral, which also appears as tiny dots called poppy seeds that are scattered between the other spots. Associated with this mineral are traces of ancient organic compounds. (Organic compounds contain carbon and are fundamental to life on Earth, but they also exist in the absence of biology.)

What does this have to do with life?

All living organisms on Earth harness energy through oxidation-reduction (redox) reactions – transferring electron particles from chemicals known as reductants to compounds named oxidants. On Earth, for example, structures called mitochondria in animal cells transfer electrons from glucose (a reductant) to oxygen (an oxidant). Some rock dwelling bacteria use other kinds of organic compound instead of glucose, and ferric iron instead of oxygen.

The new Nature paper builds on abstracts presented at the Lunar and Planetary Science Conference, held in Houston in March 2025, but with more detail and the added weight of peer review. It confirms that the pale spots are associated with organic matter, and that they contain ferrous iron and sulphur – specifically, an iron-sulphide mineral.

The most plausible interpretation is that redox reactions occurred within the rock after it formed, transferring electrons from organic matter to ferric iron and sulphate, and producing bleached zones where ferric iron was depleted.

Notably, these reactions – especially sulphate reduction – don’t typically occur at the low temperatures this rock experienced over its history. Unless microbes are involved, that is. Microbial oxidation of organic matter can also produce phosphate minerals, like those found at Cheyava Falls.

Without getting samples back to laboratories on Earth, there’s only so much we can really know about what happened at Cheyava Falls four billion years ago. Even so, no entirely satisfying non-biological explanation accounts for the full suite of observations made by Perseverance.

The new paper does a good job of making this clear, considering the possibilities one by one. But in astrobiology, the lack of a non-biological explanation accounts for the full suite of observations made by Perseverance.

So what happens next? First, astrobiologists around the world must explore which oxidation-reduction reactions involving iron, sulphur, organic compounds, and phosphate can occur with and without biology under conditions relevant to Cheyava Falls.

Second, Nasa and other space agencies must provide bold leadership on the Mars Sample Return mission. Yes, it will be expensive – possibly tens of billions of dollars – but the payoff could be the most important scientific discovery ever made.