Majorana fermion

fermion that is its own antiparticle

A Majorana fermion(/məˈrɑːnə ˈfɛərmɒn/[1]), also referred to as a Majorana particle, is a fermion that has the same properties as its antiparticle. Ettore Majorana, an Italian physicist, thought they would exist, in 1937. Majorana disappeared in 1938, and the particles are named after him. As Majorana fermionns are thought to have the same properties as their antiparticles, they cannot have an electric charge. Today, atomic particles with an electric charge are called Dirac fermions. An example for Dirac fermions are electrons, and positrons; they have the same properties, but their electric charge is different.

Majorana fermions are named after Ettore_Majorana. This shows him in the 1930s.

Neutrinos do not have an electric charge, and might be Majorana fermions, but their status is unclear

Theory

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The concept goes back to Majorana's suggestion of 1937.[2] Majorana suggested that neutral spin-​12 particles can be described by a real wave equation (the Majorana equation). The wave functions of particle and antiparticle are related by complex conjugation. For this reason, they would be identical to their antiparticle.

The difference between Majorana fermions and Dirac fermions can be expressed mathematically in terms of the creation and annihilation operators of second quantization: The creation operator   creates a fermion in quantum state   (described by a real wave function), whereas the annihilation operator   annihilates it (or, equivalently, creates the corresponding antiparticle). For a Dirac fermion the operators   and   are distinct, whereas for a Majorana fermion they are identical. The ordinary fermionic annihilation and creation operators   and   can be written in terms of two Majorana operators   and   by

 
 

In supersymmetry models, neutralinos—superpartners of gauge bosons and Higgs bosons—are Majorana.

Standard model of particle physics

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The standard model of physics has no Majorana fermions, all particles are Dirac fermions. There are neutrinos, and anti-neutrinos. In the standard model, neutrinos have no mass, though. The question how to differentiate between neutrinos and anti-neutrinos is not settled yet.

Extensions to the standard model

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There are different extensions of the standard model. One of them is called Minimal Supersymmetric Standard Model. It allows for supersymmetry, and can transform one kind of particle, the bosons, into the other, the fermions. In condensed matter physics, bound Majorana fermions can appear as quasiparticle excitations—the collective movement of several individual particles, not a single one, and they are governed by non-abelian statistics.

References

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  1. "Quantum Computation possible with Majorana Fermions" on YouTube, uploaded 19 April 2013, retrieved 5 October 2014; and also based on the physicist's name's pronunciation.
  2. Majorana, Ettore; Maiani, Luciano (2006). "A symmetric theory of electrons and positrons". In Bassani, Giuseppe Franco (ed.). Ettore Majorana Scientific Papers. pp. 201–33. doi:10.1007/978-3-540-48095-2_10. ISBN 978-3-540-48091-4. S2CID 17529013. Translated from: Majorana, Ettore (1937). "Teoria simmetrica dell'elettrone e del positrone". Il Nuovo Cimento (in Italian). 14 (4): 171–84. Bibcode:1937NCim...14..171M. doi:10.1007/bf02961314. S2CID 18973190.