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quantumaniac:


The Earth Before Oxygen
Microfossils found in Australia show that more than 3.4 billion years ago, bacteria  that fed on sulphur compounds to survive, thrived on an Earth that had no oxygen —a finding that boosts hopes life has existed on Mars and elsewhere, according to a 2011 study by researchers from the University of Western Australia and Oxford University.

The team said the remains of microbes, located in ancient sedimentary rocks that have triggered debate for nearly a decade, have been confirmed as the earliest fossils ever recorded.


The sample came from the remote Pilbara region of Western Australia, a site called Strelley Pool, where the microbes, after dying, had been finely preserved between quartz sand grains. Pilbara has some of the planet’s oldest rock formations, set down in the so-called Archean Eon when the infant Earth was a primeval water world, with seas that were the temperature of a hot bath.

In 2002, another team of scientists, working in the same region just 35 kilometres (20 miles) away, said they had found bacteria fossils in the same formation. But the claim was disputed, with some experts saying that the tiny pockmarks were not the signatures of once-living organisms but the result of mineralization of the rocks.Drawing on the latest electron microscopy and spectroscopy techniques, the authors of the new study say they have triple proof that their sample is biological in origin.The marks measure only about 10 millionths of a metre (0.0004 inches) long. Their shape and clustering are not only consistent with bacterial cells, say the scientists.They also have minute crystals of pyrite, an iron-and-sulphur compound also known as fool’s gold, which are a clear by-product of metabolising sulphur and sulphates, according to their argument.The team, led by David Wacey of the University of Western Australia, report the finding in the journal Nature Geoscience.“At last we have good solid evidence for life over 3.4 billion years ago. It confirms there were bacteria at this time, living without oxygen,” Martin Brasier, a professor at Oxford University, said in a press release.Sulphur-loving bacteria “are still common today”, added Brasier. The image top of page shows a 3D reconstruction of a 3.4 billion-year-old microfossil about 10 micrometers in diameter from Western Australia (L). Cross sections through the reconstruction (R) emphasize the spheroidal nature of this ancient cell. According to a study published in “Nature Geoscience”, microfossils were discovered in a 3.4 billion-year-old sandstone at the base of of Strelley Pool in western Australia.

quantumaniac:

The Earth Before Oxygen

Microfossils found in Australia show that more than 3.4 billion years ago, bacteria  that fed on sulphur compounds to survive, thrived on an Earth that had no oxygen —a finding that boosts hopes life has existed on Mars and elsewhere, according to a 2011 study by researchers from the University of Western Australia and Oxford University.

The team said the remains of microbes, located in ancient sedimentary rocks that have triggered debate for nearly a decade, have been confirmed as the earliest fossils ever recorded.
The sample came from the remote Pilbara region of Western Australia, a site called Strelley Pool, where the microbes, after dying, had been finely preserved between quartz sand grains. Pilbara has some of the planet’s oldest rock formations, set down in the so-called Archean Eon when the infant Earth was a primeval water world, with seas that were the temperature of a hot bath.

In 2002, another team of scientists, working in the same region just 35 kilometres (20 miles) away, said they had found bacteria fossils in the same formation. But the claim was disputed, with some experts saying that the tiny pockmarks were not the signatures of once-living organisms but the result of mineralization of the rocks.

Drawing on the latest electron microscopy and spectroscopy techniques, the authors of the new study say they have triple proof that their sample is biological in origin.The marks measure only about 10 millionths of a metre (0.0004 inches) long. Their shape and clustering are not only consistent with bacterial cells, say the scientists.

They also have minute crystals of pyrite, an iron-and-sulphur compound also known as fool’s gold, which are a clear by-product of metabolising sulphur and sulphates, according to their argument.
The team, led by David Wacey of the University of Western Australia, report the finding in the journal Nature Geoscience.

“At last we have good solid evidence for life over 3.4 billion years ago. It confirms there were bacteria at this time, living without oxygen,” Martin Brasier, a professor at Oxford University, said in a press release.
Sulphur-loving bacteria “are still common today”, added Brasier. 

The image top of page shows a 3D reconstruction of a 3.4 billion-year-old microfossil about 10 micrometers in diameter from Western Australia (L). Cross sections through the reconstruction (R) emphasize the spheroidal nature of this ancient cell. According to a study published in “Nature Geoscience”, microfossils were discovered in a 3.4 billion-year-old sandstone at the base of of Strelley Pool in western Australia.

(Source: dailygalaxy.com)

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quantumaniac:

LHCb
Standing for Large Hadron Collider beauty, the LHCb is one of the six particle detector experiments at CERN. One of the primary goals of the detector is to solve the mystery of the Matter-Antimatter symmetry in the universe.
Matter, known as baryonic matter, and anti-matter, likewise known as anti-baryonic matter - are obviously not present in symmetrical amounts in the universe, but current theories says that they should be. When matter and anti-matter collide, they explode and demolish one another in an impressive show - and this should have happened at the beginning of the universe, and the result should have been a matter-less existence. However, baryonic matter prevailed - and the scientists at LHCb hope to determine why.

quantumaniac:

LHCb

Standing for Large Hadron Collider beauty, the LHCb is one of the six particle detector experiments at CERN. One of the primary goals of the detector is to solve the mystery of the Matter-Antimatter symmetry in the universe.

Matter, known as baryonic matter, and anti-matter, likewise known as anti-baryonic matter - are obviously not present in symmetrical amounts in the universe, but current theories says that they should be. When matter and anti-matter collide, they explode and demolish one another in an impressive show - and this should have happened at the beginning of the universe, and the result should have been a matter-less existence. However, baryonic matter prevailed - and the scientists at LHCb hope to determine why.