English

Superalgebraic structure of Lorentz transformations

General Physics 2018-08-15 v1 High Energy Physics - Theory

Abstract

Modern relativistic theory of the second quantization of fermion and boson fields is based on the use of the mathematical apparatus of C*-algebras and Lie superalgebras. In this case, for fermions, the Lorentz transformations are considered as Bogolyubov transformations of creation and annihilation operators. However, in this approach one can not obtain an explicit form of the Dirac gamma-matrices. The mathematical apparatus of the superalgebraic representation of the algebra of the second quantization of spinors is developed in the article. It is based on the use of density in the impulse space of Grassmann variables and their derivatives. It is shown that the Dirac matrices and the Lorentz transformation generators can be expressed in terms of such densities. A superalgebraic form of the Dirac equation and the vacuum state vector are constructed. It is shown that in the superalgebraic form of the complex Clifford algebra the generators corresponding to the Dirac gamma matrices are not equivalent. Clifford vector corresponding to diagonal matrix annihilates the vacuum, and the remaining ones give nonzero values. This means that there is asymmetric direction corresponding to the time axis

Keywords

Cite

@article{arxiv.1707.03687,
  title  = {Superalgebraic structure of Lorentz transformations},
  author = {V. V. Monakhov},
  journal= {arXiv preprint arXiv:1707.03687},
  year   = {2018}
}

Comments

Preprint of Proc. of Intern. Scientific Meeting PIRT-2017. Moscow, 3-6 July, 2017

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