
Physicist Leo Kouwenhoven ended a 75-year hunt for the tricky Majorana fermion â a particle that is its own antiparticle â by creating one on a chip
What is a Majorana fermion?
It is named for the physicist Ettore Majorana, who found that a particle could be its own antiparticle. If a particle has properties with values unequal to zero, then its antiparticle has the opposite values. What that means is that all the properties of a Majorana fermion, the charge, energy, what have you, itâs all zero. It is a particle, but it doesnât have properties that we can measure. That makes it very mysterious. It also makes it difficult to find.
Why hunt for these tricky particles?
My background is quantum computing. Measurement is problematic for a quantum computer, because observation changes the quantum state. But if you donât have an apparatus that can measure a Majorana fermion, you cannot change it. Its insensitivity makes it a robust quantum state. This could lead towards qubits that do not collapse. Usually everything dies, but these would be very robust and could live for a long time.
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Qubits store information. How would these particles do that?
The information is stored in a topological number. Itâs like in a MĂśbius ring: there is just one twist. You can deform the ring, but it doesnât change the twist number. If the twist number is the code for information, thatâs a very robust way of encoding.
As someone who isnât from a particle physics background, how did you get into the particle-hunting game?
In condensed matter physics, we also hunt particles â known as quasiparticles. Theyâre not so well known as the high-energy particles theyâre chasing at CERN. In the last decade or so, the field has discovered some very interesting quasiparticles. One of them is the Majorana.
How did you find the Majorana?
We made one. The Majorana comes out of the superposition of an electron and a âholeâ â the absence of an electron in a metal. By applying a magnetic field to semiconducting nanowires laid across a superconductor, you can move electrons along these wires, creating two points in space that each mimic half an electron. The electrons go back and forth, so the hole jumps from left to right. If it spends an equal amount of time on each side, then, quantum mechanically, itâs in a superposition of being on the left and right. If itâs stable, then we call it a particle. Itâs not a Majorana that only comes by quickly and then is gone again. You can keep it and look at it as long as you like.
Now youâve found the Majorana, whatâs next?
Usually, if you exchange two particles, their quantum state changes by 1 or -1. If you change it once more, it goes back to the same old state. In contrast, the Majoranas have different phase factors, so you only go back to your old state by switching four times, instead of two. Thereâs no other particle in nature that we know of which has this property. So itâs not just a new particle; it also opens up a new class of particles. Iâm not sure if they exist in nature, but I think we can create them by designing nanostructures. And I think thatâs extremely cool.
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Leo Kouwenhoven is a professor of physics at Delft University of Technology in the Netherlands. He ended the 75-year hunt for the Majorana fermion by creating it on a chip
This article appeared in print under the headline âOne minute with⌠Leo Kouwenhovenâ