PARIS (AFP) ― Scientists on Wednesday said they had recorded the first real-time images of atoms moving in a molecule, a feat that captured movement lasting less than one millionth of a billionth of a second.
The exploit entailed directing an ultra-fast laser onto molecules of nitrogen and of oxygen. Its pulse of light knocked a single electron out of its orbit around one of the atoms.
The electron tumbled back onto the molecule, causing a tiny collision that, like ripples in a pond, proved a “backlight” of energy. Sensors picked up a movement of joined atoms vibrating.
The research, published in the journal Nature, was headed by Louis DiMauro, a professor of physics of Ohio State University.
The molecules that were studied are very simple ― oxygen and nitrogen make up most of the atmosphere ― but the hope is to progress to imaging of more interesting fare.
Drug designers could be among the beneficiaries.
“You could use this to study individual atoms,” DiMauro said in a press release.
“But the greater impact to science will come when we can study reactions between more complex molecules. Looking at two atoms ― that’s a long way from studying a more interesting molecule like a protein.”
In a separate technical breakthrough, also reported in Nature, physicists at CERN used microwaves to manipulate “anti-matter” atoms, once a staple of sci-fi but now one of the big frontiers of particle research.
In theory, there should be equal amounts of matter and its opposite, known as anti-matter, as a result of the Big Bang that created the cosmos.
But clearly there is not, otherwise the physical Universe would not exist.
When a matter atom meets an anti-matter atom, they cancel each other out in a burst of energy. So, for some reason, there is a far greater abundance of matter than anti-matter.
Scientists poring over this mystery have laboured to find out more about elusive anti-matter atoms.
In recent years, they have isolated anti-atoms and then stored them ― but handling them is a fiendishly hard task, given the risk of destroying them through mere contact.
The latest achievement, led by the so-called ALPHA team at CERN (European Center for Nuclear Research) in Geneva, entailed confining antihydrogen atoms in a magnetic trap and bombarding them with microwaves.
The energy kick forced the atoms out of the trap, providing some vital clues about their properties ― an “anti-atomic fingerprint,” in the scientists’ words.
The exploit entailed directing an ultra-fast laser onto molecules of nitrogen and of oxygen. Its pulse of light knocked a single electron out of its orbit around one of the atoms.
The electron tumbled back onto the molecule, causing a tiny collision that, like ripples in a pond, proved a “backlight” of energy. Sensors picked up a movement of joined atoms vibrating.
The research, published in the journal Nature, was headed by Louis DiMauro, a professor of physics of Ohio State University.
The molecules that were studied are very simple ― oxygen and nitrogen make up most of the atmosphere ― but the hope is to progress to imaging of more interesting fare.
Drug designers could be among the beneficiaries.
“You could use this to study individual atoms,” DiMauro said in a press release.
“But the greater impact to science will come when we can study reactions between more complex molecules. Looking at two atoms ― that’s a long way from studying a more interesting molecule like a protein.”
In a separate technical breakthrough, also reported in Nature, physicists at CERN used microwaves to manipulate “anti-matter” atoms, once a staple of sci-fi but now one of the big frontiers of particle research.
In theory, there should be equal amounts of matter and its opposite, known as anti-matter, as a result of the Big Bang that created the cosmos.
But clearly there is not, otherwise the physical Universe would not exist.
When a matter atom meets an anti-matter atom, they cancel each other out in a burst of energy. So, for some reason, there is a far greater abundance of matter than anti-matter.
Scientists poring over this mystery have laboured to find out more about elusive anti-matter atoms.
In recent years, they have isolated anti-atoms and then stored them ― but handling them is a fiendishly hard task, given the risk of destroying them through mere contact.
The latest achievement, led by the so-called ALPHA team at CERN (European Center for Nuclear Research) in Geneva, entailed confining antihydrogen atoms in a magnetic trap and bombarding them with microwaves.
The energy kick forced the atoms out of the trap, providing some vital clues about their properties ― an “anti-atomic fingerprint,” in the scientists’ words.
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Articles by Korea Herald