Thursday, November 03, 2022

VELIKOVSKY WAS RIGHT

How magnetism could help explain Earth’s formation


A peculiar property of the Earth’s magnetic field could help us to work out how our planet was created 4.5 billion years ago, according to a new scientific assessment.


Peer-Reviewed Publication

UNIVERSITY OF LEEDS

Artist's concept of collision 

IMAGE: IMAGE COURTESY OF NASA/JPL view more 

CREDIT: NASA/JPL

There are several theories about how the Earth and the Moon were formed, most involving a giant impact. They vary from a model where the impacting object strikes the newly formed Earth a glancing blow and then escapes, through to one where the collision is so energetic that both the impactor and the Earth are vaporized. 

Now scientists at the University of Leeds and the University of Chicago have analysed the dynamics of fluids and electrically conducting fluids and concluded that the Earth must have been magnetized either before the impact or as a result of it. 

They claim this could help to narrow down the theories of the Earth-Moon formation and inform future research into what really happened. 

Professor David Hughes, an applied mathematician in the School of Mathematics at the University of Leeds, said: “Our new idea is to point out that our theoretical understanding of the Earth’s magnetic field today can actually tell us something about the very formation of the Earth-Moon system.  

“At first glance, this seems somewhat surprising, and previous theories had not recognized this potentially important connection.”  

This new assessment is based on the resilience of Earth’s magnetic field, which is maintained by a rotating and electrically conducting fluid in the outer core, known as a geodynamo.  

Professor Fausto Cattaneo, an astrophysicist at the University of Chicago, said: “A peculiar property of the Earth’s dynamo is that it can maintain a strong magnetic field but not amplify a weak one.  

The scientists therefore concluded that if the Earth’s field were to get switched off, or even reduced to a very small level, it would not have the capability to kick in again. 

“It is this remarkable feature that allows us to make deductions about the history of the early Earth; including, possibly, how the Moon was formed,” added Professor Cattaneo. 

Professor Hughes added: “And if that is true, then you have to think, where did the Earth’s magnetic field come from in the first place?  

“Our hypothesis is that it got to this peculiar state way back at the beginning, either pre-impact or as an immediate result of the impact.   

“Either way, any realistic model of the formation of the Earth–Moon system must include magnetic field evolution. “ 

Ends 


Further information 

Picture courtesy of NASA 

You can read the full article, entitled “How was the Earth–Moon system formed? New insights 

from the geodynamo”  here 

Contact University of Leeds press officer Kersti Mitchell via k.mitchell@leeds.ac.uk with media enquiries. 

University of Leeds  

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