In the history of
continental1 drift, India has been a mysterious record-holder. More than 140 million years ago, India was part of an immense supercontinent called Gondwana, which covered much of the Southern Hemisphere. Around 120 million years ago, what is now India broke off and started slowly migrating north, at about 5 centimeters per year. Then, about 80 million years ago, the continent suddenly sped up,
racing2 north at about 15 centimeters per year -- about twice as fast as the fastest modern tectonic drift. The continent collided with Eurasia about 50 million years ago, giving rise to the Himalayas.
For years, scientists have struggled to explain how India could have drifted
northward3 so quickly. Now
geologists4 at MIT have offered up an answer: India was pulled northward by the combination of two subduction zones -- regions in the Earth's
mantle5 where the edge of one tectonic plate sinks under another plate. As one plate sinks, it pulls along any connected landmasses. The geologists reasoned that two such sinking plates would provide twice the pulling power, doubling India's drift
velocity6.
The team found
relics7 of what may have been two subduction zones by sampling and dating rocks from the Himalayan region. They then developed a model for a double subduction system, and
determined8 that India's ancient drift velocity could have depended on two factors within the system: the width of the
subducting9 plates, and the distance between them. If the plates are
relatively10 narrow and far apart, they would likely cause India to drift at a faster rate.
The group incorporated the measurements they obtained from the Himalayas into their new model, and found that a double subduction system may indeed have driven India to drift at high speed toward Eurasia some 80 million years ago.
"In earth science, it's hard to be completely sure of anything," says Leigh Royden, a professor of geology and geophysics in MIT's Department of Earth,
Atmospheric11 and Planetary Sciences. "But there are so many pieces of evidence that all fit together here that we're pretty convinced."
Royden and colleagues including Oliver Jagoutz, an associate professor of earth, atmospheric, and planetary sciences at MIT, and others at the University of Southern California have published their results this week in the journal Nature Geoscience.