Unlocking secrets of how fossils form
- Date:
- September 16, 2015
- Source:
- American Chemical Society
- Summary:
- Fossils tell amazing stories and inspire them, too -- just think of this summer's 'Jurassic World' blockbuster. But because some of the processes that preserve fossils are not well understood, there's still more information that they could reveal. Now scientists report a new way to probe fossils to find out how these ancient remains formed in greater detail than before.
Fossils tell amazing stories and inspire them, too -- just think of this summer's "Jurassic World" blockbuster. But because some of the processes that preserve fossils are not well understood, there's still more information that they could reveal. Now scientists report in ACS' journal Analytical Chemistry a new way to probe fossils to find out how these ancient remains formed in greater detail than before.
When most organisms die, they biodegrade and leave little behind. But if they get trapped in sediments that harbor few bacteria and loads of dissolved minerals, they can become fossilized and preserved for millions of years. Scientists use a variety of techniques on the ancient specimens to determine details about lifestyles and diets, as well as information about the geographical distribution of the creatures. One of those methods called scanning electron microscopy, or SEM, showed particular promise for revealing new information about fossils. So Amauri J. Paula and colleagues expanded on this method.
The researchers used a large-field SEM approach to analyze a shrimp fossil from the Araripe Basin, a place in northeastern Brazil known among paleontologists as a treasure trove of flying pterosaur remains. The shrimp specimen dates back to the Cretaceous period, when dinosaurs still roamed the planet. The technique provided evidence for the first time that a rare fossilization process occurred in the basin. It also showed that the fossil over millions of years developed a surprising fractal characteristic -- a still-unexplained, repeating pattern most commonly recognized in snowflakes but also found in structures as large as spiral galaxies.
Story Source:
The above post is reprinted from materials provided by American Chemical Society. Note: Materials may be edited for content and length.
Journal Reference:
- Naiara C. Oliveira, João H. Silva, Olga A. Barros, Allysson P. Pinheiro, William Santana, Antônio A. F. Saraiva, Odair P. Ferreira, Paulo T. C. Freire, Amauri J. Paula. Large-Field Electron Imaging and X-ray Elemental Mapping Unveil the Morphology, Structure, and Fractal Features of a Cretaceous Fossil at the Centimeter Scale. Analytical Chemistry, 2015; 150915131825003 DOI: 10.1021/acs.analchem.5b02815
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