A small, battered diamond found in the gravel strewn along a shallow riverbed in Brazil has provided evidence of a vast “wet zone” deep inside the Earth that could hold as much water as all the world’s oceans put together.
The water is not sloshing around inside the planet, but is held fast within minerals in what is known as the Earth’s transition zone, which stretches from 410 km to 660 km beneath the surface.
“It’s not a Jules Verne-style ocean you can sail a boat on,” said Graham Pearson, a geologist who studied the stone at the University of Alberta. The water-rich zone could transform scientists’ understanding of how some of the Earth’s geological features arose.
Tests on the diamond revealed that it contained a water-rich mineral formed in the zone. Researchers believe that the gemstone, which is oblong and about 5mm long, was blasted to the surface from a depth of around 500km by an explosive volcanic eruption of molten rock called kimberlite. Pearson said the gem is worth about $20 at most. The stone was found in 2008 by artisan miners working the Juina riverbeds in Mato Grosso in Western Brazil.
Pearson and his team were running tests on the diamond in the hope of finding minerals they could use to work out its age. But by chance they discovered a speck of mineral called ringwoodite, a form of olivine that forms under extremely high pressures. The mineral inclusion was so small it was invisible to the naked eye.
For half a century, scientists have suspected that ringwoodite made up much of the deep Earth, because olivine is so widespread underground. But no one had ever found any ringwoodite from Earth’s interior that proved the idea beyond doubt. In the transition zone where the diamond and its ringwoodite formed, the pressure reaches 200,000 atmospheres.
Tests on the mineral found that around 1.5 per cent of its weight is water. “That doesn’t sound like much, but when you calculate the vast volumes of ringwoodite thought to exist in the deep Earth, the amount of water might be as high as that contained in all the world’s oceans,” Pearson said. That amounts to more than one billion billion tonnes of water. — © Guardian Newspapers Limited, 2014