Sound waves reveal diamond cache deep in Earth's interior
There may be more than a quadrillion tons of diamond hidden in the Earthâs interior, according to a new study from MIT and other universities. But the new results are unlikely to set off a diamond rush. The scientists estimate the precious minerals are buried more than 100 miles below the surface, far deeper than any drilling expedition has ever reached.
The ultradeep cache may be scattered within cratonic roots â" the oldest and most immovable sections of rock that lie beneath the center of most continental tectonic plates. Shaped like inverted mountains, cratons can stretch as deep as 200 miles through the Earthâs crust and into its mantle; geologists refer to their deepest sections as âroots.â
In the new study, scientists estimate that cratonic roots may contain 1 to 2 percent diamond. Considering the total volume of cratonic roots in the Earth, the team figures that abo ut a quadrillion (1016) tons of diamond are scattered within these ancient rocks, 90 to 150 miles below the surface.
âThis shows that diamond is not perhaps this exotic mineral, but on the [geological] scale of things, itâs relatively common,â says Ulrich Faul, a research scientist in MITâs Department of Earth, Atmospheric, and Planetary Sciences. âWe canât get at them, but still, there is much more diamond there than we have ever thought before.â
Faulâs co-authors include scientists from the University of California at Santa Barbara, the Institut de Physique du Globe de Paris, the University of California at Berkeley, Ecole Polytechnique, the Carnegie Institution of Washington, Harvard University, the University of Science and Technology of China, the University of Bayreuth, the University of Melbourne, and University College London.
A sound glitch
Faul and his colleagues came to their conclusion after puzzling ove r an anomaly in seismic data. For the past few decades, agencies such as the United States Geological Survey have kept global records of seismic activity â" essentially, sound waves traveling through the Earth that are triggered by earthquakes, tsunamis, explosions, and other ground-shaking sources. Seismic receivers around the world pick up sound waves from such sources, at various speeds and intensities, which seismologists can use to determine where, for example, an earthquake originated.
Scientists can also use this seismic data to construct an image of what the Earthâs interior might look like. Sound waves move at various speeds through the Earth, depending on the temperature, density, and composition of the rocks through which they travel. Scientists have used this relationship between seismic velocity and rock composition to estimate the types of rocks that make up the Earthâs crust and parts of the upper mantle, also known as the lithosphere.
However, in using seismic data to map the Earthâs interior, scientists have been unable to explain a curious anomaly: Sound waves tend to speed up significantly when passing through the roots of ancient cratons. Cratons are known to be colder and less dense than the surrounding mantle, which would in turn yield slightly faster sound waves, but not quite as fast as what has been measured.
âThe velocities that are measured are faster than what we think we can reproduce with reasonable assumptions about what is there,â Faul says. âThen we have to say, âThere is a problem.â Thatâs how this project started.â
Diamonds in the deep
The team aimed to identify the composition of cratonic roots that might explain the spikes in seismic speeds. To do this, seismologists on the team first used seismic data from the USGS and other sources to generate a three-dimensional model of the velocities of seismic waves traveling through the Earthâs major c ratons.
Next, Faul and others, who in the past have measured sound speeds through many different types of minerals in the laboratory, used this knowledge to assemble virtual rocks, made from various combinations of minerals. Then the team calculated how fast sound waves would travel through each virtual rock, and found only one type of rock that produced the same velocities as what the seismologists measured: one that contains 1 to 2 percent diamond, in addition to peridotite (the predominant rock type of the Earthâs upper mantle) and minor amounts of eclogite (representing subducted oceanic crust). This scenario represents at least 1,000 times more diamond than people had previously expected.
âDiamond in many ways is special,â Faul says. âOne of its special properties is, the sound velocity in diamond is more than twice as fast as in the dominant mineral in upper mantle rocks, olivine.â
The researchers found that a rock composition of 1 to 2 percen t diamond would be just enough to produce the higher sound velocities that the seismologists measured. This small fraction of diamond would also not change the overall density of a craton, which is naturally less dense than the surrounding mantle.
âThey are like pieces of wood, floating on water,â Faul says. âCratons are a tiny bit less dense than their surroundings, so they donât get subducted back into the Earth but stay floating on the surface. This is how they preserve the oldest rocks. So we found that you just need 1 to 2 percent diamond for cratons to be stable and not sink.â
In a way, Faul says cratonic roots made partly of diamond makes sense. Diamonds are forged in the high-pressure, high-temperature environment of the deep Earth and only make it close to the surface through volcanic eruptions that occur every few tens of millions of years. These eruptions carve out geologic âpipesâ made of a type of rock called kimberlite (named after the tow n of Kimberley, South Africa, where the first diamonds in this type of rock were found). Diamond, along with magma from deep in the Earth, can spew out through kimberlite pipes, onto the surface of the Earth.
For the most part, kimberlite pipes have been found at the edges of cratonic roots, such as in certain parts of Canada, Siberia, Australia, and South Africa. It would make sense, then, that cratonic roots should contain some diamond in their makeup.
âItâs circumstantial evidence, but weâve pieced it all together,â Faul says. âWe went through all the different possibilities, from every angle, and this is the only one thatâs left as a reasonable explanation.â
This research was supported, in part, by the National Science Foundation. â¨Source: Google News US Science | Netizen 24 United States