Showing posts with label Fossil Cache. Show all posts
Showing posts with label Fossil Cache. Show all posts
Thursday, May 25
Old Fossil Unveils Early Life
Cutting-edge technology has revealed new insights about a globally famous fossil treasure trove, which may provide critical evidence concerning early life on Earth.
Scientists investigating the 400 million-year-old fossil cache, discovered in the remote northeastern region of Scotland, report that their results display a higher level of molecular preservation in these fossils than what was previously expected.
Fresh scrutiny of the exquisitely preserved treasure trove from Aberdeenshire has enabled scientists to identify the chemical fingerprints of the various organisms within it.
Just as the Rosetta Stone helped Egyptologists translate hieroglyphics, the team hopes these chemical codes can help them decipher more about the identity of the life forms, that other more ambiguous fossils represent.
The spectacular fossil ecosystem near the Aberdeenshire village of Rhynie was discovered in 1912, mineralized and encased by chert – hard rock composed of silica. Known as the Rhynie chert, it originates from the Early Devonian period – about 407 million years ago – and has a significant role to play in scientists’ understanding of life on earth.
Researchers combined the latest non-destructive imaging with data analysis and machine learning to analyze fossils from collections held by National Museums Scotland and the Universities of Aberdeen and Oxford. Scientists from the University of Edinburgh were able to probe deeper than has previously been possible, which they say could reveal new insights about less well-preserved samples.
Employing a technique known as FTIR spectroscopy – in which infrared light is used to collect high-resolution data – researchers found impressive preservation of molecular information within the cells, tissues, and organisms in the rock.
Since they already knew which organisms most of the fossils represented, the team was able to discover molecular fingerprints that reliably discriminate between fungi, bacteria, and other groups.
These fingerprints were then used to identify some of the more mysterious members of the Rhynie ecosystem, including two specimens of an enigmatic tubular “nematophyte”. READ MORE...
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