& çâÌæÚUæð´ ·¤è ¥ôÚU Îð¹Ùæ ÁæÚUè ÚU¹ð´ ¥ÍæüÌ ¥ÂÙð ÜÿØ ÂÚU ŠØæÙ ÚU¹ð´Ð ãæÚU Ù ×æÙð´, €UØô´ç·¤ ·¤æ× ·¤ÚUÙð âð ¥æ·¤ô ©gðàØ ·¤è Âýæç# ãôÌè ãñ ¥õÚU ÁèßÙ ·¤æ ¹æÜèÂÙ ÎêÚU ãôÌæ ãñÐ ÖÜð ãè ÁèßÙ ×ð´ ç·¤ÌÙè Öè ·¤çÆÙæ§ü €UØô´ Ù ¥æ°, çÁ™ææâæ ¥õÚU ©ˆâæã ÕÙæ° ÚU¹ð´Ð ŠØæÙ ÚU¹ð´, ÜÿØ ã×ðàææ ¥æ·Ԥ Âæâ ãôÌð ãñ´ çÁ‹ãð´ ÂæÙð ·Ô¤ çÜ° ÂýØæ⠥样¤Öè Öè àæéM¤ ·¤ÚU â·¤Ìð ãñ´Ð The Origin Of Life Ancient meteorite offers new clues Independent.co.uk

Scientists have found clues in an ancient meteorite that could explain the origins of life - not just on our planet but elsewhere.

The new discovery looked at rocks that formed during the very birth of our solar system, 4.5 billion years ago. By peering back into that ancient time, astronomers can try and understand how our Earth came to support life.

And by using those same findings, researchers might be able to understand whether there could be life in other solar systems.

The research confirms that important organic materials appear to have been formed at the beginnings of our solar system. By looking at the isotopic signature of the compounds within the rocks, they can find the "fingerprints” of key elements -including carbon, hydrogen, oxygen, nitrogen, and sulphur, all of which are both central to the beginnings of life and have been found inside those rocks.

If such organic materials can be formed through relatively simple processes in the early solar system, then they might be widespread elsewhere, too. That might mean that life could be found more often in other planetary systems than we had expected, the researchers suggest.

The kind of ancient meteorite studied by the University of Manchester scientists are incredibly rare: known as carbonaceous chondrites, they comprise only a few percent of all known meteorites. And they are an incredibly important and unusual way of looking back at the very beginnings of the solar system that surrounds us, since the Earth tends to wipe out such records.

"Earth is a dynamic planet - processes such as plate tectonics and erosion have erased most of the early Earth records," said Romain Tartese of Manchester's School of Earth and Environmental Sciences.