Like ordinary hydrogen, a single electron orbiting a proton nucleus, antihydrogen is the simplest of atoms, a single positron (antielectron) orbiting a single antiproton. CERN’s ALPHA experiment was first to trap antihydrogen in a magnetic bottle, using a superconducting octupole magnet. (Images by Chukman So, copyright © 2011 Wurtele Research Group. All rights reserved.)
The ALPHA collaboration at CERN in Geneva has scored another coup on the antimatter front by performing the first-ever spectroscopic measurements of the internal state of the antihydrogen atom. Their results are reported in a forthcoming issue of Nature and are now online.
Ordinary hydrogen atoms are the most plentiful in the universe, and also the simplest - so simple, in fact, that some of the most fundamental physical constants have been discovered by measuring the tiny energy shifts resulting from the magnetic and electric interactions of hydrogen’s proton nucleus with its single orbiting electron.
Antihydrogen, on the other hand, is rare, with single positrons (antielectrons) orbiting single antiprotons - difficult to make, and even more difficult to hold onto. Indeed antihydrogen had never been trapped until ALPHA succeeded in doing so in 2010.
In a recent series of trials, the ALPHA researchers created and captured hundreds of antihydrogen atoms in a magnetic bottle, then probed their internal states by bathing them in microwave radiation that flipped the spins of the positrons, causing the immediate ejection of the atoms from the magnetic trap and their annihilation on the trap wall.
Neither electrons nor positrons really spin, of course. "Spin" is the name for an internal quantum state of some particles and has just two values, up and down. In hydrogen, the interaction of the spin states of the electron and proton splits the ground state (the atom’s lowest energy) and is known as hyperfine splitting; in astronomy, hyperfine splitting is the source of the signature 21-centimeter emission line of hydrogen.
Antihydrogen should behave the same way, and the frequency of the microwave radiation required to flip its spins thus provides a direct measure of the difference in energy between the two hyperfine states of antihydrogen.
"To measure the hyperfine structure of antihydrogen we tune the frequency of the microwaves," says Jonathan Wurtele, a member of the Accelerator and Fusion Research Division (AFRD) at the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab), a professor of physics at the University of California at Berkeley, and a long-time member of the ALPHA collaboration. As of now the measure is imprecise, because the size of the energy difference depends on the magnitude of the magnetic field in ALPHA’s antihydrogen trap, but Wurtele says, "Our newest experimental apparatus is already under construction, and these initial experiments indicate that we’ll soon have the techniques to make precise measurements."
How to catch an anti-atom
Berkeley Lab scientists played key roles in designing and modeling ALPHA’s Minimum Magnetic Field Trap, a magnetic bottle created by superconducting magnets whose fields capture and hold antihydrogen atoms. Although electrically neutral, the separation of the anti-atoms’ negatively charged antiprotons and positively charged positrons, plus their spins, gives them a magnetic moment. Thus - as long as they aren’t moving too fast - they are vulnerable to capture by the trap’s magnetic fields.
One advantage of working with antimatter is that it is easy to work with individual atoms, which is not the case for ordinary hydrogen. Joel Fajans, a founding member of ALPHA who is also a member of AFRD and a physics professor at UC Berkeley, explains that if one were trying to capture ordinary hydrogen atoms in a similar trap, "the vacuum in these traps is always contaminated with hydrogen, so how could you distinguish the background hydrogen from the deliberately trapped hydrogen?"
But, says Fajans, "you can’t trap antihydrogen accidentally; it just doesn’t occur naturally." Antihydrogen, like all forms of antimatter, can’t co-exist with normal matter because matter and antimatter mutually annihilate in a burst of energy when they come in.
The disadvantages of experiments on antihydrogen atoms include trying to insert experimental probes without disturbing the trap’s exquisitely balanced magnetic fields. Over the past months the ALPHA researchers have been able to modify the experiment to introduce microwave radiation into the trap’s interior. In their experiments they used two different methods of gathering data, one dubbed the disappearance method and one the appearance method.
» Share this page: