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Introducing Multidimensional Dirac-Hestenes Equation

Mathematical Physics 2025-06-10 v2 math.MP

Abstract

It is easier to investigate phenomena in particle physics geometrically by exploring a real solution to the Dirac-Hestenes equation instead of a complex solution to the Dirac equation. The current research presents a formulation of the multidimensional Dirac-Hestenes equation. Since the matrix representation of the complexified (Clifford) geometric algebra CC1,n\mathbb{C}\otimes{C \kern -0.1em \ell}_{1,n} depends on the parity of nn, we examine even and odd cases separately. In the geometric algebra C1,3{C \kern -0.1em \ell}_{1,3}, there is a lemma on a unique decomposition of an element of the minimal left ideal into the product of the idempotent and an element of the real even subalgebra. The lemma is used to construct the four-dimensional Dirac-Hestenes equation. The analogous lemma is not valid in the multidimensional case, since the dimension of the real even subalgebra of C1,n{C \kern -0.1em \ell}_{1,n} is bigger than the dimension of the minimal left ideal for n>4n>4. Hence, we consider the auxiliary real subalgebra of C1,n{C \kern -0.1em \ell}_{1,n} to prove a similar statement. We present the multidimensional Dirac-Hestenes equation in C1,n{C \kern -0.1em \ell}_{1,n}. We prove that one might obtain a solution to the multidimensional Dirac-Hestenes equation using a solution to the multidimensional Dirac equation and vice versa. We also show that the multidimensional Dirac-Hestenes equation has gauge invariance.

Keywords

Cite

@article{arxiv.2411.04214,
  title  = {Introducing Multidimensional Dirac-Hestenes Equation},
  author = {S. V. Rumyantseva and D. S. Shirokov},
  journal= {arXiv preprint arXiv:2411.04214},
  year   = {2025}
}

Comments

21 pages

R2 v1 2026-06-28T19:50:37.584Z