A Comment on Background Independence in Quantum Theory

In this communication we take up the significance and purpose of selecting the proper coordinate system from the flat space‐time of non‐relativistic theories to the quantum theoretic formulation of general relativity. The universal background problem is straight forwardly framed as a momentum‐energy...

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Vydané v:Journal of the Chinese Chemical Society (Taipei) Ročník 63; číslo 1; s. 11 - 19
Hlavný autor: Brandas, Erkki J
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Weinheim WILEY-VCH Verlag 01.01.2016
WILEY‐VCH Verlag
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Predmet:
Black holes
Conjugate operators
Conjugates
Coordinates
Equivalence principle
General relativity
Gravitational fields
Lorentz transformations
Mathematical analysis
Matrix algebra
Momentum
Non-positive metrics
Operators (mathematics)
Quantum theory
Relativistic theory
Relativity
ISSN:0009-4536, 2192-6549, 2192-6549
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Shrnutí:In this communication we take up the significance and purpose of selecting the proper coordinate system from the flat space‐time of non‐relativistic theories to the quantum theoretic formulation of general relativity. The universal background problem is straight forwardly framed as a momentum‐energy portrait in nexus with its space‐time conjugates. The description is based on operator matrix algebra, where the related analogue of the secular equation yields a Klein‐Gordon type equation and the associated Minkowski eigentime element. The energy‐momentum and their conjugate partners are represented by spaces that have (+,−) signatures. The general theory implicates both non‐zero‐ and zero rest‐mass entities, and it is proved that the conjugate relationship between energy and time provide a simple derivation of the Schwarzschild line element for the case of a gravitational field outside a spherical non‐rotational uncharged mass. This result, indicating the appearance of a black hole as a true singularity in the energy‐time formulation, and obtained as a direct consequence of their conjugate relationship, manifests background independence in concert with Einstein’s equivalence principle. Inducing a reformulation of the Lorentz Transformation respecting the indefinite Minkowski metric, displays an interesting relation between complex dilations and indefinite metric spaces, validating the complex symmetric ansatz. It is proven that a basic quantum theoretic ansatz of momentum‐energy and their conjugates, space time, impart the celebrated Schwarzschild metric, showing contrary to the classical case, the Schwarzschild radius to be a true theoretical singularity. An linear mapping of the Lorentz transformation in the Minkowski space displays an interesting relation between complex dilation and indefinite metric spaces.
Bibliografia:ArticleID:JCCS201500067
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content type line 14
ISSN:0009-4536
2192-6549
2192-6549
DOI:10.1002/jccs.201500067