Petrographic evidence. Evidence for UHP metamorphism: garnet inclusions and exsolution mineralogy. (A) Numerous orthogonal inclusions comprising carbonates (calcite, aragonite, dolomite, and Mg calcite), graphite, and microdiamonds. (B) Radial decompression fractures surrounding quartz interpreted to have formed after coesite. Fractures infilled by later chlorite. (C) Oriented inclusion trails and crystallographically controlled exsolution of rutile. (D) Numerous rutile and apatite exsolution needles. (E) Apatite and rutile exsolution lamellae. (F) Amphibole exsolution lamellae. (G and H) Quartz exsolution laths. Qtz, quartz; Coes, coesite; Mdia, microdiamond. Credit: Science Advances (2022). DOI: 10.1126/sciadv.abo2811
A trio of researchers from James Cook University, working with a colleague from the University of Adelaide, has found metamorphic diamonds in rocks near Australia’s north coast. In their paper published in the journal Science AdvancesAlexander Edgar, Ioan Sanislav, Paul Dirks and Carl Spandler, describe how they found the tiny diamonds and why they believe the find will help reveal more about the early history and formation of Australia.
Metamorphic diamonds are very rare, they only form in very specific places. They are also very small—from microscopic down to nano-sized. The unique diamonds form in subduction zones—the pressure of opposing plates grinding against one another over millions of years results in the creation of diamonds so small they cannot be seen with the naked eye, which is why they are so very rarely found. They have only ever been found in six other places on Earth. In this new effort, the researchers found a bunch of them inside of rocks along the Clarke River Fault, which came about when crustal blocks were pushed together approximately 500 million years ago.
The researchers began investigating the rocks along the fault line after they were told by one of their students of some rock formations they had observed that looked like they might have been revealed when one of the tectonic plates pushed them above the surface of the ground around them .
The researchers ventured into the site and collected some of the rocks and brought them back to their lab for study. There they sliced them into very thin slabs and used Raman spectroscopy to help identify the minerals held within. In so doing, they found evidence of silica, amphibole, apatite, lamella of rutile, coesite, quartz and most importantly, metamorphic diamonds.
The researchers note that the diamonds they observed were the first to be found in the Gondwana-Pacific part of the Terra Australis Orogen. They also suggest that because metamorphic diamonds can only be created under very specific conditions, the study of them and the locations where they are found could provide more clues about how Australia was formed.
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Alexander Edgar et al, Metamorphic diamond from the northeastern margin of Gondwana: Paradigm shifting implications for one of Earth’s largest orogens, Science Advances (2022). DOI: 10.1126/sciadv.abo2811
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Citation: Discovery of metamorphic diamonds in northeast Queensland could provide clues about how Australia was formed (2022, July 29) retrieved 30 July 2022 from https://phys.org/news/2022-07-discovery-metamorphic-diamonds-northeast-queensland .html
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