CERN Scientists Capture Atoms Of Elusive ‘Antimatter’ For First Time

The physicists combined positrons and antiprotons in beginning with 30,000 antiprotons cooled to 200˚ above absolute zero, or 200 kelvin, and 2 million positrons cooled to about 40 kelvin.

The experiment took place inside a magnetic trap known as an Ioffe-Pritchard online today in Nature.

That trap was only ‘deep’ enough to capture the slowest-moving antiatoms.

After mixing the protons and positrons, the trap was turned off and electric fields used to sweep any remaining charged particles out the device.

They then turned off the magnetic trap and looked for any lingering antiatoms drifting into the material and annihilating to produce detectable particles.

In 335 trials, the physicists saw a total of 38 trapped atoms—about one every 10 trials.

Physics breakthrough as scientists at CERN capture atoms of elusive ‘antimatter’ for first time

Starship Enterprise takes on a Klingon warship in Star Trek. The spacecraft used antimatter to power its ‘warp drive’

Now scientists say they have captured a sample of real-life antimatter for the first time.

In an astonishing breakthrough, a team of British and international physicists were able to ‘trap’ 38 atoms of anti-hydrogen in a laboratory for a fraction of a second.

While the experiment is unlikely to lead to the warp engines, anti-matter drives or the faster than light travel of Star Trek, it could shed light on the nature and origins of the Universe.

Antimatter is the mirror of ordinary matter. Normal atoms are made up of positively-charged nuclei orbited by negatively-charged electrons.

However, their antimatter counterparts are the wrong way round. They have negative nuclei and positively-charged electrons.

When matter and antimatter meet they instantly annihilate each other, releasing a burst of energy.

Since it was first proposed by the British physicist Paul Dirac in 1931, antimatter has been a staple of science fiction.

An antimatter reactor powers the USS Enterprise in the TV and film series Star Trek, while an antimatter bomb hidden under Rome plays a key role Dan Brown’s thriller Angels & Demons.

These clouds of particles were then introduced to a similar cold cloud of positrons – antimatter electrons.

The two kinds of particle combined to form atoms of hydrogen antimatter which were successfully trapped by a magnetic field for one sixth of a second.

Past efforts to create antimatter managed to generate anti-hydrogen atoms that blinked out of existence almost as soon as they were created.

Prof Rob Thompson, head of physics and astronomy at the University of Calgary, one of the 42 Alpha investigators, said: ‘This is a major discovery.

‘It could enable experiments that result in dramatic changes to the current view of fundamental physics or in confirmation of what we already know now.

‘We’ve been able to trap about 38 atoms, which is an incredibly small amount, nothing like what we would need to power Star Trek’s Starship Enterprise or even to heat a cup of coffee.

‘Now we can start working on the next step which is to use tools to study it.’

Theoretically, a single pound of antimatter would contain more destructive power than the largest H-bomb. However, creating and holding even a tiny amount of antimatter is so difficult and expensive, the chances of it being used in a superweapon are remote.

The new research, published today in the journal Nature, involved researchers at the European nuclear research facility at Cern, Geneva.

Using the Anti-hydrogen Laser Physics Apparatus, or Alpha, the scientists cooled negatively charged antiprotons – the mirror version of hydrogen nuclei – and squeezed them into a matchstick-sized cloud 20 mm long and 1.4 mm wide.

Professor Paul Nolan, from the University’s Department of Physics, explains: ‘When antihydrogen decays inside the ALPHA experiment, it emits particles, called pions, from the point at which it exists.

‘Our detector surrounds the area where antihydrogen is formed and for each pion emitted we get three points as it travels outwards.

‘Using a computer we can then construct a line between these points and trace it back to the origin of the antihydrogen. Being able to study these particles brings us closer to understanding the composition of anti-matter and the physical properties of our Universe.’

The ALPHA detector comprises an electronic trap to hold positrons and antiprotons (yellow), inside a magnetic trap to catch anti-hydrogen atoms (red and green), inside a particle detector gray) to detect the annihilation of the atoms

The ALPHA experiment at CERN has succeeded in capturing antimatter for a split-second

The experiments could help scientists unravel one of the great unsolved mysteries of the universe.

When the Big Bang gave birth to the universe 13.7 billion years ago, equal amounts of matter and antimatter were created, scientists believe.

But the cosmos today is completely dominated by ordinary matter. Scientists have long wondered where all the missing antimatter went.

Prof Mike Charlton, from the University of Swansea, said: ‘Hydrogen is the simplest of all atoms and anti-hydrogen is the easiest type of antimatter to produce in the laboratory.

‘Understanding it will hopefully enable us to shed light on why almost everything in the known universe consists of matter rather than antimatter.’

A graph that shows in milliseconds all of the collisions between the particles that resulted in 38 antihydrogen atoms being created and trapped

By David Derbyshire
Last updated at 12:22 PM on 18th November 2010

Source: Daily Mail

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