Madagascar’s landscape tells a story of deep time: ancient rifting and geological tilting sculpted the island’s dramatic topography and steered its rivers, setting the stage for the evolution of its extraordinary biodiversity.
A new study published in Science Advances reveals that Madagascar’s striking landscape was shaped by not one, but two great rifting events, separated by nearly 80 million years. These tectonic shifts first tore the island from Africa, then from India, tilting and reshaping its terrain and setting the stage for life to flourish in isolation.
Madagascar first separated from Africa about 170 million years ago, forming a rugged western escarpment and an eastward-tilted plateau. For tens of millions of years, its rivers drained mainly eastward across this landscape.
But around 90 million years ago, a second rift opened on the island’s eastern side, separating Madagascar from India and the Seychelles. The crust thinned again — but this time the island tilted in the opposite direction, toward the west. The consequences were dramatic: rivers reversed course, the island’s main water divide shifted eastward, and a new, steep escarpment formed along the Indian Ocean margin.
“The key to understanding Madagascar’s landscape lies in its water divide,” says Romano Clementucci from ETH Zurich, lead author of the new Science Advances study. “When the island tilted after each rifting event, the main water divide, the line separating rivers flowing east or west, jumped across the island, transforming its hydrology and erosion patterns."
The island’s drainage system was almost completely reorganized. Old rivers reversed direction or abandoned their channels to follow the new westward slope, and erosion patterns flipped as well.
Over time, the western escarpment evolved into a worn-down landscape of remnant highlands and low-relief plateaus, while the east developed a young, linear, and steep escarpment - today’s most recognizable feature of Madagascar.
Madagascar is now one of the world’s most celebrated biodiversity hotspots: over 90% of its mammals and reptiles and more than 80% of its plants exist nowhere else on Earth. Researchers have long attributed this extraordinary biological richness to climate and isolation from the continents. But recent studies, including those by Liu et al. (2024) and Clementucci et al. (2025), add a deeper geological dimension to the story.
The landscape itself may act as a «speciation pump», the migration of the divide didn’t just change where rivers flow, but where life could evolve.
This perspective echoes the vision of Alexander von Humboldt, who two centuries ago proposed a unified theory for understanding biodiversity patterns. The new study contributes to this theory by extending biodiversity drivers from classic climatic hypotheses to erosion process.
"Our work adds a new piece to the puzzle,” Clementucci says. "We show how ancient tectonic forces reshaped Madagascar’s surface, tilting the island and shifting the main rivers and mountain divides. Over millions of years, this created fragmented environments where species evolved independently, especially along the island's dramatic eastern escarpment."
The broader implication is a shift in how we view so-called “stable” regions such as Madagascar, South Africa, India, Brazil, or Australia and other passive margins. These areas are often seen as geologically quiet, yet they host some of the planet’s richest biodiversity. This study shows they are still highly dynamic, with landscapes that continue to evolve - changes which leave a lasting mark on biodiversity.
Science Advances
Computational simulation/modeling
Not applicable
Madagascar’s landscape evolution: A tale of two rifts
15-Oct-2025
This research is funded by the Swiss National Science Foundation (SNF) under project number 200432.