Commuting simplicity and closure constraints for 4D spin-foam models

Journal article


Publication Details

Author(s): Han M, Thiemann T
Journal: Classical and Quantum Gravity
Publisher: IOP PUBLISHING LTD
Publication year: 2013
Volume: 30
Journal issue: 23
ISSN: 0264-9381


Abstract


Spin-foam models are supposed to be discretized path integrals for quantum gravity constructed from the Plebanski-Holst action. The reason for there being several models currently under consideration is that no consensus has been reached for how to implement the simplicity constraints. Indeed, none of these models strictly follows from the original path integral with commuting B fields, rather, by some nonstandardmanipulations one always ends up with non-commuting B fields and the simplicity constraints become in fact anomalous which is the source for there being several inequivalent strategies to circumvent the associated problems. In this paper, we construct a new Euclidian spin-foam model which is constructed by standard methods from the Plebanski-Holst path integral with commuting B fields discretized on a 4D simplicial complex. The resulting model differs from the current ones in several aspects, one of them being that the closure constraint needs special care. Only when dropping the closure constraint by hand and only in the large spin limit can the vertex amplitudes of this model be related to those of the FK gamma. model but even then the face and edge amplitude differ. Interestingly, a non-commutative deformation of the B-IJ variables leads from our new model to the Barrett-Crane model in the case of gamma =infinity.



FAU Authors / FAU Editors

Han, Muxin Dr.
Lehrstuhl für Theoretische Physik
Thiemann, Thomas Prof. Dr.
Lehrstuhl für Theoretische Physik


How to cite

APA:
Han, M., & Thiemann, T. (2013). Commuting simplicity and closure constraints for 4D spin-foam models. Classical and Quantum Gravity, 30(23). https://dx.doi.org/10.1088/0264-9381/30/23/235024

MLA:
Han, Muxin, and Thomas Thiemann. "Commuting simplicity and closure constraints for 4D spin-foam models." Classical and Quantum Gravity 30.23 (2013).

BibTeX: 

Last updated on 2018-10-08 at 19:53