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Inclusion-bearing Rough Diamond


Sulfide, inclusion-bearing rough diamond from the Jwaneng Mine in Botswana

A sulfide, inclusion-bearing rough diamond from the Jwaneng Mine in Botswana. This optical photomicrograph shows the natural diamond growth surface. Below the surface and at the center is a brass-colored, hexagonal-shaped grain of iron sulfide surrounded by an irregular black rim. The rim is caused by internal fracture of the diamond on its ascent to the Earth's surface via explosive volcanism. Sulfide grains such as these are removed for sulfur isotopic analysis.

More about this Image
National Science Foundation (NSF)-supported geologists James Farquhar and Boswell Wing from the University of Maryland have found that tiny inclusions encased in diamonds preserve information about the cycling of material between the Earth's atmosphere, crust and mantle some 3 billion years ago.

The researchers studied ratios of isotopes--atoms that are of the same type, but have a slightly different size--and tracked distinctive "isotopic signatures" that are unique to rocks that were created in the same place. By tagging a rock throughout its life cycle, researchers can use isotopic signatures to draw conclusions about previously unknown parts of Earth's early history, such as how the atmosphere evolved and the origin of early life-forms.

Farquhar and Wing, along with colleagues from other institutions, have shown that sulfide inclusions in diamonds from Botswana contain a characteristic ratio of the three isotopes of sulfur. This finding indicates that these sulfur atoms completed an entire geochemical cycle on Earth--from the air to the rocks to everywhere in between. This first documentation of the complete recycling of ancient sulfur adds to the knowledge of the dynamic processes that shaped our planet's evolution.

To learn more about this research, see the NSF News Tip Sulfur Signature in Diamonds Reveals New Facts about Early Earth. (Year of image: 2003)

Credit: Jeff Harris, University of Glasgow, U.K.
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