[meteorite-list] Research Shows Organic Molecules Can Survive Meteorite Impact

From: Ron Baalke <baalke_at_meteoritecentral.com>
Date: Tue, 12 Nov 2013 15:05:49 -0800 (PST)
Message-ID: <201311122305.rACN5nob018366_at_zagami.jpl.nasa.gov>

http://www.nhm.ac.uk/about-us/news/2013/november/life-may-have-arrived-from-space125606.html

Life may have arrived from space
Natural History Museum (United Kingdom)
11 November 2013

[Image]
False-coloured scanning electron microscope image showing organic material
in meteorite debris.

New research shows that organic molecules, on which life is based, can
survive the impact from a meteorite.

Reporting in the journal Nature Geoscience, mineralogist Dr Kieran Howard
and his team have discovered intact organic molecules inside debris from
a meteorite impact. Dr Howard was a researcher at the Museum when he performed
the analyses.

This is the first evidence that any organic material, either inside a
meteorite or already on Earth, can survive the impact of a meteorite striking
the planet at high speed.

The discovery lends weight to the idea of panspermia ? the suggestion
that life on our planet was seeded by material falling from space.

The debris studied by the team was thrown up by a meteorite impact in
Western Tasmania, Australia, leaving a 1.2km diameter crater known as
Darwin Crater.

The meteorite crash-landed on Earth approximately 800,000 years ago at
a speed of up to 18kms per second, and with a possible temperature on
impact of more than 1,700?C.

It was thought that any organic material would be vaporised by the extreme
temperature and pressure of a collision. But the researchers found organic
matter within the impact debris from local swamps and rainforests present
when the meteorite struck.

Extra-terrestrial life

"We were surprised by our discovery," said Dr Howard. "We have long assumed
any organic molecules, such as amino acids would not survive a meteorite
impact. The evidence we have now supports an old hypothesis that impacts
might have delivered the building blocks of life to the early Earth."

It has been experimentally proven that some bacteria can survive the heat
and speed of entering our atmosphere, but whether anything could survive
an actual impact was uncertain.

Tiny time capsules

The evidence for the new research comes from "impact glasses", smooth
spheres that form when the energy of a meteorite impact melts the rock
it strikes and sends it hurtling through the air. These droplets are flung
huge distances, solidifying as they travel.

The impact glasses used in the study were strewn up to 20km from the impact
site at Darwin Crater.

Inside the glasses the team found tiny inclusions of organic material,
sometimes less than 0.001mm in diameter. They were able to analyse this
material and confidently link it to plants that existed in the nearby
swamps and rainforests of the time.

Life on Mars?

Organic material usually degrades over time, but inside the impact glasses
it was perfectly preserved for nearly one million years.

Impact glasses act as tiny time capsules, preserving a record of the local
environment at the time of the meteorite strike. This adds new dimensions
to the search for evidence of life on Mars.

Since material ejected from Earth could reach Mars in as little as 30,000
years, organic material originating in Earth impact glasses could be found
on the surface of the red planet.

Mars' own impact glasses could also have preserved material from a time
when we know the planet was much wetter and warmer, and may have been
able to support life.
Received on Tue 12 Nov 2013 06:05:49 PM PST


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