Lagrangian Formulation of an Infinite Derivative Real Scalar Field Theory in the Framework of the Covariant Kempf-Mangano Algebra in a \((D+1)\)-dimensional Minkowski Space-time

In 2017, G. P. de Brito and co-workers suggested a covariant generalization of the Kempf-Mangano algebra in a \((D+1)\)-dimensional Minkowski space-time [A. Kempf and G. Mangano, Phys. Rev. D \textbf{55}, 7909 (1997); G. P. de Brito, P. I. C. Caneda, Y. M. P. Gomes, J. T. Guaitolini Junior, and V. N...

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Bibliographic Details
Published inarXiv.org
Main Authors Izadi, A, Moayedi, S K
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 01.12.2019
Subjects
Algebra
Expanding universe theory
Field theory
Form factors
Minkowski space
Physics - General Relativity and Quantum Cosmology
Physics - High Energy Physics - Theory
Quantum theory
Relativity
Spacetime
Wave equations
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Summary:In 2017, G. P. de Brito and co-workers suggested a covariant generalization of the Kempf-Mangano algebra in a \((D+1)\)-dimensional Minkowski space-time [A. Kempf and G. Mangano, Phys. Rev. D \textbf{55}, 7909 (1997); G. P. de Brito, P. I. C. Caneda, Y. M. P. Gomes, J. T. Guaitolini Junior, and V. Nikoofard, Adv. High Energy Phys. \textbf{2017}, 4768341 (2017)]. It is shown that reformulation of a real scalar field theory from the viewpoint of the covariant Kempf-Mangano algebra leads to an infinite derivative Klein-Gordon wave equation which describes two bosonic particles in the free space (a usual particle and a ghostlike particle). We show that in the low-energy (large-distance) limit our infinite derivative scalar field theory behaves like a Pais-Uhlenbeck oscillator for a spatially homogeneous field configuration \(\phi(t,\vec{\textbf{x}})=\phi(t)\). Our calculations show that there is a characteristic length scale \(\delta\) in our model whose upper limit in a four-dimensional Minkowski space-time is close to the nuclear scalar, i.e., \(\delta_{max}\sim \delta_{nuclear\ scale}\sim 10^{-15}\, m\). Finally, we show that there is an equivalence between a non-local real scalar field theory with a non-local form factor \({\cal K}(x-y)= -\frac{\square_x}{(1-\frac{\delta^2}{2}\square_x)^2} \ \delta^{(D+1)}(x-y)\) and an infinite derivative real scalar field theory from the viewpoint of the covariant Kempf-Mangano algebra.
ISSN:2331-8422
DOI:10.48550/arxiv.1903.03765