Fractionally charged: An illustration of the experimental set-up with extremely pure gallium arsenide. Quasiparticles, shown in yellow, travel along the edge and have one quarter the charge of an electron.

Credit: Genia Brodsky, Weizmann Institute.

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SYDNEY: Israeli physicists have discovered bizarre 'quasiparticles' which have one quarter the charge of an electron, and may be useful in quantum computing.

Quasiparticles are formed within a group of electrons and behave as if they are particles. But they only have a fraction of the charge of an electron, according to lead researcher Merav Dolev from the Weizmann Institute of Science in Israel, who announced the discovery this week. This is weird because no single particle can have a fraction of electric charge.

Electron soup

Until now, researchers have only been able to form quasiparticles with one-third, one-fifth or one-seventh of the charge on an electron. Quasiparticles with even denominators, such as one-quarter or one-sixth, are expected to behave completely differently to quasiparticles with odd denominators.

In this study, the researchers trapped a 'soup' of electrons in an extremely pure sample of gallium arsenide, so that the electrons could only move in two directions – that is, they could move forward and backward, and side to side, but not up and down. As they also reported in a paper in the British journal Nature earlier this year, they then placed this sample in a magnetic field.

In this precise set-up, with the extremely pure gallium arsenide, researchers could see these quarter-charged quasiparticles.

It's the quasiparticles with even denominators, such as one-quarter, that are more interesting, because scientists expect the order in which they interact changes the outcome. So, if you switch quasiparticle A with quasiparticle B, then switch B with C, it is not the same as switching B with C then A with B.

"[This] is very non-intuitive," said Dolev. "All of the 'regular' particles – which is what we are used to – do not behave like that." Quasiparticles with odd denominations of electron charge do not share this curious behaviour.

The outcome is that a quasiparticle can 'remember' the path it has taken. Dolev expects this property to be exploited in an exotic type of quantum computer called a 'topological quantum computer'.

The computing would be done "by rotating quasiparticles, one around the other." Dolev said. "All you care about, then, is which quasiparticle went around which, not the exact path. This is what makes it 'topological', since you only care about the topology of the path."