UNDERGROUND EVEREST+ MOUNTAINS

MOUNTAINS buried 400 miles underground ''could be bigger than Everest. 

An underground 'mountain' has been discovered that lies 400 miles beneath Earth's surface that's taller than Everest.

A study by Princeton scientists into the  boundary between the upper and lower mantle of Earth have surprisingly found ridges and clefts that are potentially rougher than anything on Earth.

They are located at a boundary 410 miles  [600 kilometeres] straight down into the earth from the planet's surface.

Dr. Wembo Wu, one of the geophysicists  on the paper said : ''In other words, stronger topography than the Rocky Mountains or the Appalachians, is present at the 660-km boundary.''

Using wave data from a 8.2 magnitude earthquake  in Bolivia, mountains and other topography were discovered  on the base of the boundary.

The earthquake was the second largest deep earthquake ever recorded and took place in 1994.

The most powerful waves on the planet come from giant earthquakes, that can generate shock waves which travel through the earth's core to the other side of the planet in all directions and back again.

The data from the shock waves allows data scientists to study deep into the Earth by modeling wave data on this kind of topography that could have caused it to scatter in such a way.

They do using powerful computers such as Princeton's Tiger cluster to simulate complicated behavior of scattering waves.

Dr. Wu, a now a postdoctoral researcher at the California Institute of Technology, added : ''We know that almost all objects have surface roughness and therefore scatter light.

That's why we can see these objects - the scattering waves carry information about the surface's roughness.

In this study, we investigated scattered seismic waves traveling inside the Earth to to constrain the roughness of the earth's 600 km boundary.'

Those studies can tell us a lot about the Earth's formation and how heat and material can travel through the Earth's in different layers.

But no one knows exactly how these huge jutting mountain structures may have evolved, but it's likely a result of movement of material and chemical mixing between the layers.

Dr. Wu said : ''The smoother areas of the 660 km boundary could result from more thorough vertical mixing,  while the tougher, mountainous areas may have formed where the upper and lower mantle don't mix as well.''

Speaking to Dr. Jessica Irving, who led the research said :

 What's exciting about these results is that they give us new information to understand the fate of ancient tectonic plates, which have descended into the mantle, and where ancient mantle material might still reside.''

The full study was published in Science. [Courtesy Daily Mail].