* Astronomy

Meteorite Tracking
An international team of scientists has begun installing meteorite-tracking cameras on the Nullarbor, in south-eastern Western Australia, in an attempt to learn more about the universe.

For the past two years the team has successfully recorded material falling from the sky at a site just outside Kalgoorlie-Boulder, using a highly sophisticated camera.

The success of the trial has prompted the scientists, from Britain, Czechoslovakia and Australia, to install permanent cameras at three remote pastoral stations on the Nullarbor.
Phil Bland from the Imperial College of London says tracking meteorites could help unlock some of the mysteries of the universe.

"With meteorites, we've got a random bag of rocks and what we're trying to do is work out where those different rocks come from, if we get that, it should help us work out how planets were formed, how the solar system came together and also how you make planets generally out in the universe" - Phil Bland .

The Nullarbor Plain is thought to be a former seabed. About 20-25 million years ago, the whole area was uplifted by crustal movements. The Nullarbor Plain now is a vast area of flat, almost treeless, arid or semi-arid country immediately north of the Great Australian Bight. The word Nullarbor is derived from the Latin for "no trees".

It is the world's largest single piece of limestone, and occupies an area of about 200,000 sq km (77,200 sq miles). At its widest point, it stretches about 1200 km from east to west between South Australia (SA) and Western Australia (WA).

Meteorites contain a record of processes ranging from the pre-solar stellar evolution of our galactic neighbourhood, to protoplanetary disk formation and evolution, and the accretion and differentiation of planetesimals and protoplanets in the early solar system.
But unlike geologists, planetary scientists must interpret this unique record with no spatial context to help them: with precise orbital data for only a few samples, we don't really know where individual meteorites come from. Camera networks, designed to calculate orbits and fall positions of meteorites based on observations of fireballs, have been in operation for several decades but have recovered only a small number of samples – meteorites are very difficult to find in vegetated areas.
The researchers have solved this problem by setting up a network in a place where they already know they can recover meteorites – the Nullarbor desert of Western Australian.
The first camera was installed at a test site in Australia in October 2003 and has performed flawlessly since that date, taking images of fireballs, several large enough to have dropped meteorites.

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