English

Time evolution in deparametrized models of loop quantum gravity

General Relativity and Quantum Cosmology 2017-08-02 v1 High Energy Physics - Theory

Abstract

An important aspect in understanding the dynamics in the context of deparametrized models of LQG is to obtain a sufficient control on the quantum evolution generated by a given Hamiltonian operator. More specifically, we need to be able to compute the evolution of relevant physical states and observables with a relatively good precision. In this article, we introduce an approximation method to deal with the physical Hamiltonian operators in deparametrized LQG models, and apply it to models in which a free Klein-Gordon scalar field or a non-rotational dust field is taken as the physical time variable. This method is based on using standard time-independent perturbation theory of quantum mechanics to define a perturbative expansion of the Hamiltonian operator, the small perturbation parameter being determined by the Barbero-Immirzi parameter β\beta. This method allows us to define an approximate spectral decomposition of the Hamiltonian operators and hence to compute the evolution over a certain time interval. As a specific example, we analyze the evolution of expectation values of the volume and curvature operators starting with certain physical initial states, using both the perturbative method and a straightforward expansion of the expectation value in powers of the time variable. This work represents a first step towards achieving the goal of understanding and controlling the new dynamics developed in [25, 26].

Keywords

Cite

@article{arxiv.1702.01688,
  title  = {Time evolution in deparametrized models of loop quantum gravity},
  author = {Mehdi Assanioussi and Jerzy Lewandowski and Ilkka Mäkinen},
  journal= {arXiv preprint arXiv:1702.01688},
  year   = {2017}
}

Comments

23 pages, 18 figures

R2 v1 2026-06-22T18:10:29.311Z