Exotic Particle Changes Flavor as Scientists Watch

LiveScience Staff

Scientists have observed the rare phenomenon of one type of exotic particle transforming into another, which could reveal secrets about the evolution of the universe.

The particles are two types of chargeless, nearly massless species called neutrinos, which come in three flavors: muon, electron and tau. In past experiments, physicists have measured the change of muon neutrinos to tau neutrinos and electron neutrinos to muon or tau neutrinos, but no one has definitively seen muon neutrinos turn into electron neutrinos.

Now, two separate experiments — one in Japan and one in Minnesota — have both found evidence for this transformation as well.

Detecting neutrinos

Scientists of the Main Injector Neutrino Oscillation Search (MINOS) experiment at the Department of Energy's Fermi National Accelerator Laboratory announced their findings today (June 24). The results are consistent with, and significantly constrain, a measurement reported 10 days ago by the Japanese Tokai-to-Kamioka (T2K) experiment, which announced an indication of this type of transformation. [Strange Quarks and Muons, Oh My! Nature's Tiniest Particles]

The MINOS study sent a beam of muon neutrinos 450 miles (735 kilometers) through the Earth, from the Main Injector accelerator at Fermilab in Batavia, Ill., to a 5,000-ton neutrino detector, located half a mile underground in the Soudan Underground Laboratory in northern Minnesota.

The neutrinos' trip from Fermilab to Soudan takes about four hundredths of a second, giving the neutrinos enough time to change their identities.

MINOS recorded a total of 62 electron neutrino-like events, which is a likely indication that there were 62 electron neutrinos present at Soudan. If muon neutrinos didn't transform into electron neutrinos, MINOS should have seen only 49 events. The T2K experiment showed 71 such electron-neutrino events, though the two experiments use different methods and analysis techniques to look for this rare transformation.

The balance of matter

The new finding could have major implications for our understanding of the history of the universe. If muon neutrinos can transform into electron neutrinos, neutrinos could be the reason that the Big Bang produced more matter than antimatter, leading to the universe as it exists today. To solve this mystery, scientists want to calculate how often different flavors of neutrinos change into each other, and compare that with the rate of change among neutrinos' antimatter partners, antineutrinos.

If it turns out that the rules of transformation are different between neutrinos and antineutrinos, that asymmetry could help explain why matter vastly outnumbers antimatter in the universe.

MINOS will continue to collect data until February 2012. The T2K experiment was interrupted in March when the severe earthquake in Japan damaged its muon neutrino source. Scientists expect to resume operations of the experiment at the end of the year.

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Scientists say on way to solving anti-matter mystery

Robert Evans

GENEVA (Reuters) – European scientists reported on Monday the creation and capture of anti-hydrogen atoms in a novel magnetic trap and said it put them on track to solving one of the great cosmic mysteries -- the make-up of anti-matter.

Anti-matter is of intense interest outside the global scientific community because it has often been cited as a potential source of boundless and almost cost-free energy.

The announcement from CERN, the European Organization for Nuclear Research, came just three weeks after another of the three teams working separately on the problem at the particle research center near Geneva said they had briefly made and caught the elusive atoms for the first time.

"With these alternative methods of producing and eventually studying anti-hydrogen, anti-matter will not be able to hide its properties from us for much longer," said Yasunori Yamazaki of the team that scored the latest breakthrough.

Anti, or neutral, matter is believed to have been created in the same quantities as conventional matter -- the substance of everything visible in the universe including life on earth -- at the moment of the Big Bang 13.7 billion years ago.

A theme of much science fiction, it was only discovered by U.S. physicist David Anderson in 1932.

As the latest breakthrough was reported, CERN engineers were closing down the centre's showpiece Large Hadron Collider or LHC for a two-month break after eight months of scientific success in research into how the universe began.

OPERATIONS EXTENDED

CERN's Director-General Rolf Heuer told Reuters that new discoveries were rolling in so fast that it was likely the initial phase of LHC operations would be stretched to the end of 2012, a year longer than planned.

His deputy Sergio Bertolucci said the LHC was moving rapidly into totally new territories of scientific knowledge and the coming months could bring real insight into the "dark matter" that makes up 25 percent of the universe.

Physicists and cosmologists speculate that "dark matter" -- so called because it reflects no light and cannot be seen -- could account for at least some of the missing anti-matter, particles which were first spotted at CERN in 2002.

Some suggest it may have also some relation to the "dark energy" that constitutes about 70 percent of the universe leaving only 5 percent for the visible parts -- galaxies, stars and planets -- that can be observed from earth or nearby.

Monday's announcement said the "ASACUSA" experiment, in a CERN storage ring known as the Antiproton Decelerator or AD, captured "significant numbers" of anti-hydrogen atoms in flight in a particle trap called CUSP.

Last month the parallel, and complementary, ALPHA experiment at the AD captured 38 anti-hydrogen atoms in flight and held them fleetingly, making possible initial observations of their properties and behavior.

New equipment developed by ASACUSA, ALPHA and a third experiment, ATRAP, has overcome the problem that prevented close study of anti-particles until now -- the fact that when they meet other matter they self-destruct.

(Editing by Jonathan Lynn and Jon Hemming)

http://news.yahoo.com/s/nm/20101206/sc_nm/us_science_cern

What is the Difference Between Antimatter and Matter?

Patrick Michael

Antimatter in Today's Society

When Dan Brown wrote "Angels & Demons" in 2000 and the novel was adapted to film in 2009, the general public learned about antimatter for the first time. Though some may think that Dan Brown delved into science-fiction when he brought antimatter into his novel, this strange form of matter is just as real as its more common counterpart.

But antimatter is far important than just for the plot of a fictional novel. It is currently used in medical imaging technology and would make an excellent fuel due to its reactivity if enough could be produced and harnessed. But what exactly is antimatter? To answer that question, it is helpful to first look at matter at its most fundamental level.

Matter

Matter is everything in our world that can be quantified by our senses. It can exist as a solid, liquid, gas or other strange forms under certain conditions. But at the atomic level, all matter is created the same way. Although there are still smaller particles, the lowest level that retains the characteristics of the specific element is called the atom.

The main particles that make up the atom are called neutrons, protons and electrons. For the purpose of simplicity, consider the element hydrogen, which only has one of each particle. An atom of hydrogen has at its center one neutron (true of all elements.) That neutron, which has no electric charge, is stuck to a proton, which has a positive charge. They are held together by what is called the "strong force," one of the four fundamental forces of physics. Finally, the electron, with a negative charge, orbits or rotates around the nucleus or center.

Antimatter

Surprisingly, the structure of an atom of antimatter is very similar. Again, consider hydrogen, or as it would be called in the realm of antimatter: "antihydrogen." First, an atom of antihydrogen also has one neutral neutron at its center. In addition, the neutron is also stuck to a proton and is orbited by an electron. The difference comes in the charge of these two particles. In an atom of antihydrogen, the proton is negative and the electron is positive.

So what's the big deal? As stated earlier, there are many practical applications of antimatter. And Dan Brown is correct in claiming that a small amount of antimatter is very dangerous. In fact, because its particles have opposite charges, if antimatter and matter come in contact, they annihilate each other and convert to energy in a violent explosion.

So Where Is the Antimatter?

Fortunately, there is far more matter than antimatter in our neighborhood of the universe or this world would be a very unpleasant place to live. Scientists do not know why there is more matter than antimatter. It could be that there are equal parts of each, with all the antimatter residing in a different part of the universe.

However, scientists do possess the knowledge and technology to create antimatter through the use of particle accelerators such as the one at CERN. But the cost to create and harness even the tiniest portion of antimatter is astronomical. As scientists continually perfect their methods and costs could potentially decrease, a debate will ensue considering the potential uses and dangers of such a powerful force.

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