NASA's Curiosity rover captured images of Martian sand ripples in 2015, revealing two distinct patterns: larger, meter-scale ripples alongside smaller, decimeter-scale "impact" ripples. Until now, it was thought that these smaller ripples were formed by wind-driven particle impacts, similar to Earth's sand ripples, while the larger ones resulted from hydrodynamic instability, akin to underwater ripples. The assumption was that Earth's physical conditions could not replicate those on Mars.

The Ben-Gurion University team, leveraging the wind tunnel at their university and the Mars tunnel at Aarhus University, demonstrated that the Martian sand ripple phenomenon could indeed be replicated on Earth. This revelation came after experimenting with tiny glass balls to simulate the finer Martian sand, a key to their breakthrough.

This research not only challenges existing theories but also opens the door to new discoveries about the processes shaping the surfaces of both Mars and Earth. Prof. Yizhaq highlighted the novelty of their approach, underscoring the potential for future research to uncover similar patterns on Earth, thus bridging the gap between terrestrial and extraterrestrial geological phenomena.

"There is much more research, both fieldwork and experimentally, needed to prove our theory, but it is amazing to propose something so radically new in a field I have been studying for over 20 years. It is exciting to go out and try to find on Earth what can clearly be seen on Mars," Prof. Yizhaq shared with enthusiasm about the future implications of their findings.

Research Report:Coevolving aerodynamic and impact ripples on Earth

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Ben-Gurion University of the Negev
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