From: Matthew Brown <[EMAIL PROTECTED]>
Date: Wed, 31 Jul 2002 15:04:09 -0700
Subject: Huge meteorite crater found underneath North Sea

http://www.newscientist.com/news/news.jsp?id=ns99992622

Phil Allen, a consultant geophysicist based near Aberdeen, discovered the
crater by chance. Petroleum giant BP had asked him to look at 3D seismic
data from a gas field four kilometres below the North Sea. During his
analysis, Allen discovered some unusual features in layers of chalk lying
above the gas field, one kilometre beneath the seabed (Nature, vol 418, p
520). 

   
 The structure of the North Sea crater is revealed by 3D seismic imaging
What Allen saw looked like a crash site. "I was flabbergasted," he says,
"I'd never seen anything like it." It wasn't until a meeting with Simon
Stewart, a BP structural geologist who also thought it looked like a crater,
that Allen took the idea seriously.

Stewart had published a paper a year earlier in which he argued that there
was a good chance an impact crater would be found somewhere in the North
Sea. Based on the frequency of asteroid impacts, the size of the North Sea
and the age of the corresponding rocks, Stewart estimated that the chance of
the area containing a small impact crater was one in two (Petroleum
Geoscience, vol 5, p 273).


Huge tsunami 


The newly discovered crater, named Silverpit after the local fishing
grounds, is 140 kilometres off the east coast of Britain (see graphic). An
asteroid between 200 and 500 metres across must have caused the crater,
which is around three kilometres across and 300 metres deep, when it
crash-landed between 60 and 65 million years ago.

The collision would not have been powerful enough to scatter debris across
the planet, but it would have created a huge tsunami that inundated the few
rocks poking up above the ocean surface in what is now Scotland.

Expensive 3D seismic imaging is not an option for most research groups.
Instead, the underlying structures of a few craters, for example Chicxulub
in Mexico, have been crudely imaged by 2D seismic data and drill cores. But
BP's commercial survey of the gas field beneath Silverpit reveals the crater
in unprecedented detail.

Although the crater's size is not particularly noteworthy, its structure is
unique. It is surrounded by at least 10 concentric fractures, and the
outermost ring is about 19 kilometres across. No other crater on Earth has
anything like them.

"It's a fantastic discovery," says Jay Melosh of the University of Arizona
at Tucson. "Given the spectacular detail revealed by the 3D seismic
reconstruction, Silverpit is likely to teach us a great deal about how such
ring systems arise."


Jupiter's moons 


That may in turn provide information about the structure of Jupiter's icy
moons, because Silverpit looks a lot like craters found on Europa and
Callisto, which have similar systems of rings.

The discovery of such a site on Earth will give scientists a unique chance
to study how these ringed craters form. The current theory is that there
must be a soft, watery layer beneath a brittle surface.

When an asteroid hits, it creates a bowl-shaped cavity that the soft layer
moves inwards to fill. As it does so, it drags the brittle surface and
cracks it. At Silverpit, it may be that the underlying layer of muddy shale
was soft enough to flow in a similar way, and finding evidence of that would
help confirm the theory.
 
  
Ralph Lorenz


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