Braiding, Majorana Fermions and the Dirac Equation

This paper explains a method of constructing algebras, starting with the properties of discrimination in elementary discrete systems. We show how to use points of view about these systems to construct what we call iterant algebras and how these algebras naturally give rise to the complex numbers, Clifford algebras and matrix algebras. The paper discusses the structure of the Schrödinger equation, the Dirac equation and the Majorana Dirac equations, finding solutions via the nilpotent method initiated by Peter Rowlands.

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Fermionic Formulation of the Ising Model

Statistical Field Theory ◽

10.1093/oso/9780198788102.003.0009 ◽

2020 ◽

pp. 319-340

Author(s):

Giuseppe Mussardo

Keyword(s):

Ising Model ◽

Dirac Equation ◽

Quadratic Form ◽

Continuum Limit ◽

Majorana Fermions ◽

Bogoliubov Transformation ◽

Crucial Aspect ◽

Creation And Annihilation Operators ◽

Order And Disorder ◽

The Continuum

A crucial aspect of the Ising model is its fermionic nature and this chapter is devoted to this property of the model. In the continuum limit, a Dirac equation for neutral Majorana fermions emerges. The details of the derivation are much less important than understanding why it is possible. The chapter emphasizes the simplicity and the exactness of the result, and covers the so-called Wigner-Jordan transformation, which brings the original Hamiltonian to a quadratic form in the creation and annihilation operators of the fermions. It covers the role played by the Bogoliubov transformation and the importance of the order and disorder operators.

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Fermions and the Dirac equation

10.1093/oso/9780198802877.003.0008 ◽

2018 ◽

Author(s):

Michael Kachelriess

Keyword(s):

Dirac Equation ◽

Lorentz Group ◽

Spinor Representation ◽

Majorana Fermions

Starting from the spinor representation of the Lorentz group,Weyl spinors and their transformation properties are derived. The Dirac equation and the properties of its solutions are discussed. Graßmann numbers and the gener-ating functional for fermions are introduced. Weyl and Majorana fermions are examined.

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Biquaternionic Dirac Equation Predicts Zero Mass for Majorana Fermions

Symmetry ◽

10.3390/sym12071144 ◽

2020 ◽

Vol 12 (7) ◽

pp. 1144

Author(s):

Avraham Nofech

Keyword(s):

Dirac Equation ◽

Outer Automorphism ◽

Charge Conjugation ◽

Majorana Fermions ◽

Algebraic Proof ◽

Conjugation Operator ◽

Equal Zero ◽

Zero Mass ◽

Mass Coefficient ◽

Pauli Algebra

A biquaternionic version of the Dirac Equation is introduced, with a procedure for converting four-component spinors to elements of the Pauli algebra. In this version, mass appears as a coefficient between the 4-gradient of a spinor and its image under an outer automorphism of the Pauli algebra. The charge conjugation operator takes a particulary simple form in this formulation and switches the sign of the mass coefficient, so that for a solution invariant under charge conjugation the mass has to equal zero. The multiple of the charge conjugation operator by the imaginary unit turns out to be a complex Lorentz transformation. It commutes with the outer automorphism, while the charge conjugation operator itself anticommutes with it, providing a second more algebraic proof of the main theorem. Considering the Majorana equation, it is shown that non-zero mass of its solution is imaginary.

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DIRAC EQUATION IN (1+3)- AND (2+2)-DIMENSIONS

International Journal of Modern Physics A ◽

10.1142/s0217751x13501145 ◽

2013 ◽

Vol 28 (24) ◽

pp. 1350114

Author(s):

J. A. NIETO ◽

C. PEREYRA

Keyword(s):

Dirac Equation ◽

Majorana Fermions ◽

Systematic Method ◽

Majorana Representation

We develop a systematic method to derive the Majorana representation of the Dirac equation in (1+3)-dimensions. We compare with similar approach in (2+2)-dimensions. We argue that our formalism can be useful to have a better understanding of possible Majorana fermions.

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