Scientists have created a model of the Earth's geological features. (Representational)
Scientists today have published new research revealing a detailed and dynamic model of the Earth's surface over the past 100 million years.
For the first time, the research provides a high-resolution understanding of how today's geophysical landscapes were created and how millions of tonnes of sediment have flowed to the oceans, according to the research.
Climate, tectonics and time combine to create powerful forces that craft the face of our planet. Add the gradual sculpting of the Earth's surface by rivers and what to us seems solid as rock is constantly changing.
However, our understanding of this dynamic process has at best been patchy.
"To predict the future, we must understand the past. But our geological models have only provided a fragmented understanding of how our planet's recent physical features formed," said lead author Tristan Salles from the University of Sydney School of Geosciences, Australia.
"If you look for a continuous model of the interplay between river basins, global-scale erosion and sediment deposition at high resolution for the past 100 million years, it just doesn't exist," said Salles.
"So, this is a big advance. It's not only a tool to help us investigate the past but will help scientists understand and predict the future, as well," said Salles.
Working with scientists in France, University of Sydney geoscientists have published this new model in the journal Science.
Using a framework incorporating geodynamics, tectonic and climatic forces with surface processes, the scientific team has presented a new dynamic model of the past 100 million years at high resolution, down to 10 kilometres, broken into frames of a million years, the research said.
"This unprecedented high-resolution model of Earth's recent past will equip geoscientists with a more complete and dynamic understanding of the Earth's surface," said second author Laurent Husson from Institut des Sciences de la Terre in Grenoble, France.
"Critically, it captures the dynamics of sediment transfer from the land to oceans in a way we have not previously been able to," said Husson.
Salles said that understanding the flow of terrestrial sediment to marine environments is vital to comprehend present-day ocean chemistry.
"Given that ocean chemistry is changing rapidly due to human-induced climate change, having a more complete picture can assist our understanding of marine environments," he said.
The model will allow scientists to test different theories as to how the Earth's surface will respond to changing climate and tectonic forces, the research said.
Further, the research provides an improved model to understand how the transportation of Earth sediment regulates the planet's carbon cycle over millions of years, it said.
"Our findings will provide a dynamic and detailed background for scientists in other fields to prepare and test hypotheses, such as in biochemical cycles or in biological evolution," said Salles.
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