Scientists discover 4.3 billion year old traces of Earth’s original crust in Canada

Scientists discover 4.3 billion year old traces of Earth’s original crust in Canada

Samples of rock harvested in Canada are thought to contain parts of Earth’s crust dating back to more than 4.3 billion years ago.

As Earth is estimated to be about 4.6 billion years old, researchers now say it’s possible that parts of our planet’s original crust still remain in place today.

Scientists found isotopic evidence of the ‘parent rocks’ of 2.7 billion-year-old samples from the Canadian Shield, suggesting Earth’s oldest crust survived the formation of this continental feature. 

Samples of rock harvested in Canada are thought to contain bits of Earth’s crust dating back to more than 4.3 billion years ago. As Earth is estimated to be about 4.6 billion years old, researchers now say it’s possible that parts of our planet’s original crust still remain

In a new study, researchers from the University of Ottawa and Carnegie Science analyzed the isotope ratios of samarium and neodymium rocks from the Superior Province, which sits just north of the Great Lakes.

These samples are composed primarily of a type of granite that’s 2.7 billion years old, and formed through the ‘recycling’ of older, magnesium-rich rocks.

‘This area of northern Quebec is the nucleus of the Canadian shield,’ explained Professor Jonathan O’Neil, of the university’s Department of Earth and Environmental Sciences.

‘Previous work had shown that if we had a flavour of something older, of this ancestor, it would be there.’

Scientists found isotopic evidence of the ‘parent rocks’ of 2.7 billion-year-old samples from the Canadian Shield (shown in shades of red), suggesting Earth’s oldest crust survived the formation of this continental feature 

Scientists found isotopic evidence of the ‘parent rocks’ of 2.7 billion-year-old samples from the Canadian Shield (shown in shades of red), suggesting Earth’s oldest crust survived the formation of this continental feature

Earth’s first crust has largely been driven back into the interior through geologic activity, making it difficult to pinpoint its nature.

But, using these specific isotopes, the researchers were able to study ‘the earliest time of the Earth.’

This, in turn, revealed the signature of the precursor rock.

Samarium-146 has a half-life of just 103 million years, which is short on a geological time scale.

In a new study, researchers from the University of Ottawa and Carnegie Science analyzed the isotope ratios of samarium and neodymium rocks from the Superior Province, which sits just north of the Great Lakes
These samples are composed primarily of a type of granite that’s 2.7 billion years old, and formed through the ‘recycling’ of older, magnesium-rich rocks

In a new study, researchers from the University of Ottawa and Carnegie Science analyzed the isotope ratios of samarium and neodymium rocks from the Superior Province, which sits just north of the Great Lakes

According to O’Neil, the results allow scientists to better pinpoint the age of the parent rock. ‘It has to be older than 4.2 billion years old, almost as old as 4.3 billion years old,’ O’Neil said. ‘So, we can piece the puzzle together to try to understand how the first continents formed’

And, while it existed at the time of Earth’s formation, it became extinct early on.

The researchers determined that the samples contained reworked crust from more than 4.2 billion years ago.

‘Now we can better understand how these nucleus of continents tabulated in time,’ O’Neil explained.

‘There’s a complex history of crustal recycling and re-melting, so the rocks are always constantly recycling and re-melting that way – and erasing lot of information about their earliest life, or where they’re coming from.’

Earth’s first crust has largely been driven back into the interior through geologic activity, making it difficult to pinpoint its nature. But, using these specific isotopes, the researchers were able to study ‘the earliest time of the Earth’

EARTH’S MISSING CRUST

Geoscientists from the University of Chicago calculated the mass before and after the collision of the India-Asia system, taking into account each of the many ways it may have been distributed.

This process is extremely slow, originating 60 million years ago, and continues today.

The new calculations revealed a huge discrepancy in the mass.

After the collision, the displaced crust could only have behaved in a few ways, the team explains.

Some was forced upward, creating the Himalayas, while some was eroded and deposited as massive sedimentary deposits in the oceans.

And, some squeezed out from the sides, forming Southeast Asia.

This, however, still leaves a large portion unaccounted for, and the researchers say this can only be explained if the missing chunk sank into the mantle.

‘Whether this result implies that plate tectonics was not at work during the earliest part of Earth history can now be investigated using our tool of studying neodymium-142 variation to track the role of truly ancient crust in building up younger, but still old, sections of Earth’s continental crust,’ said Carnegie’s Richard Carlson.

According to O’Neil, the results allow scientists to better pinpoint the age of the parent rock.

‘It has to be older than 4.2 billion years old, almost as old as 4.3 billion years old,’ O’Neil said.

‘So, we can piece the puzzle together to try to understand how the first continents, and the nucleus of our oldest continents were formed.’

Scientists found isotopic evidence of the ‘parent rocks’ of 2.7 billion-year-old samples from the Canadian Shield, suggesting Earth’s oldest crust survived the formation of this continental feature

Scientists found isotopic evidence of the ‘parent rocks’ of 2.7 billion-year-old samples from the Canadian Shield, suggesting Earth’s oldest crust survived the formation of this continental feature

Source: Daily Mail
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