S. Bäßler scite author profile

We study the nonperturbative formulation of quantum gravity defined via Euclidean dynamical triangulations (EDT) in an attempt to make contact with Weinberg's asymptotic safety scenario. We find that a fine-tuning is necessary in order to recover semiclassical behavior. Such a fine-tuning is generally associated with the breaking of a target symmetry by the lattice regulator; in this case we argue that the target symmetry is the general coordinate invariance of the theory. After introducing and fine-tuning a non-trivial local measure term, we find no barrier to taking a continuum limit, and we find evidence that four-dimensional, semiclassical geometries are recovered at long distance scales in the continuum limit. We also find that the spectral dimension at short distance scales is consistent with 3/2, a value that could resolve the tension between asymptotic safety and the holographic entropy scaling of black holes. We argue that the number of relevant couplings in the continuum theory is one, once symmetry breaking by the lattice regulator is accounted for. Such a theory is maximally predictive, with no adjustable parameters. The cosmological constant in Planck units is the only relevant parameter, which serves to set the lattice scale. The cosmological constant in Planck units is of order one in the ultra-violet and undergoes renormalization group running to small values in the infrared. If these findings hold up under further scrutiny, the lattice may provide a nonperturbative definition of a renormalizable quantum field theory of general relativity with no adjustable parameters and a cosmological constant that is naturally small in the infrared.

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Recent Results in Euclidean Dynamical Triangulations

Laiho¹,

Bäßler²,

Du³

et al. 2017

Acta Phys. Pol. B Proc. Suppl.

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We study a formulation of lattice gravity defined via Euclidean dynamical triangulations (EDT). After fine-tuning a non-trivial local measure term we find evidence that four-dimensional, semi-classical geometries are recovered at long distance scales in the continuum limit. Furthermore, we find that the spectral dimension at short distance scales is consistent with 3/2, a value that is also observed in the causal dynamical triangulation (CDT) approach to quantum gravity.

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de Sitter instanton from Euclidean dynamical triangulations

et al. 2021

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Recent results in Euclidean dynamical triangulations

Laiho¹,

Bäßler²,

Coumbe³

et al. 2017

Preprint

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Gravitationally bound quantum states of neutrons: applications and perspectives

Abele

Bäßler

Börner³

et al. 2006

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S. Bäßler

Lattice quantum gravity and asymptotic safety

Recent Results in Euclidean Dynamical Triangulations

de Sitter instanton from Euclidean dynamical triangulations

Recent results in Euclidean dynamical triangulations

Gravitationally bound quantum states of neutrons: applications and perspectives

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