This paper provides a systematic study of gauge symmetries in the dynamical fuzzy spectral triple models for quantum gravity that have been proposed by Barrett and collaborators. We develop both the classical and the perturbative quantum BV formalism for these models, which in particular leads to an explicit homological construction of the perturbative quantum correlation functions. We show that the relevance of ghost and antifield contributions to such correlation functions depends strongly on the background Dirac operator D 0 around which one perturbs, and in particular on the amount of gauge symmetry that it breaks. This will be illustrated by studying quantum perturbations around (a) the gauge-invariant zero Dirac operator D 0 = 0 in a general ( p , q ) -model, and (b) a simple example of a non-trivial D 0 in the quartic ( 0 , 1 ) -model.
BV quantization of dynamical fuzzy spectral triples / Gaunt, James; Nguyen, Hans; Schenkel, Alexander. - In: JOURNAL OF PHYSICS. A, MATHEMATICAL AND THEORETICAL. - ISSN 1751-8113. - 55:47(2022), pp. 474004-474004. [10.1088/1751-8121/aca44f]
BV quantization of dynamical fuzzy spectral triples
Schenkel, Alexander
2022-01-01
Abstract
This paper provides a systematic study of gauge symmetries in the dynamical fuzzy spectral triple models for quantum gravity that have been proposed by Barrett and collaborators. We develop both the classical and the perturbative quantum BV formalism for these models, which in particular leads to an explicit homological construction of the perturbative quantum correlation functions. We show that the relevance of ghost and antifield contributions to such correlation functions depends strongly on the background Dirac operator D 0 around which one perturbs, and in particular on the amount of gauge symmetry that it breaks. This will be illustrated by studying quantum perturbations around (a) the gauge-invariant zero Dirac operator D 0 = 0 in a general ( p , q ) -model, and (b) a simple example of a non-trivial D 0 in the quartic ( 0 , 1 ) -model.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione
