Colored Group Field Theory

A. Perez; D. Oriti; D.V. Boulatov; E.R. Livine; F. Conrady; F. David; H. Grosse; J. Ambjorn; J. Ambjorn; J. Ambjorn; J. Engle; J. Engle; J.B. Geloun; J.W. Barrett; L. Freidel; L. Freidel; L. Freidel; M. Disertori; M. Gross; M. Mulazzani; N. Sasakura; R. De Pietri; R. Gurau; R. Williams; Razvan Gurau; V. Bonzom; V.G. Turaev; W.J. Fairbairn

research

Colored Group Field Theory

Authors: A. Perez
D. Oriti
D.V. Boulatov
E.R. Livine
F. Conrady
F. David
H. Grosse
J. Ambjorn
J. Ambjorn
J. Ambjorn
J. Engle
J. Engle
J.B. Geloun
J.W. Barrett
L. Freidel
L. Freidel
L. Freidel
M. Disertori
M. Gross
M. Mulazzani
N. Sasakura
R. De Pietri
R. Gurau
R. Williams
Razvan Gurau
V. Bonzom
V.G. Turaev
W.J. Fairbairn
Publication date: 15 July 2009
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

Group field theories are higher dimensional generalizations of matrix models. Their Feynman graphs are fat and in addition to vertices, edges and faces, they also contain higher dimensional cells, called bubbles. In this paper, we propose a new, fermionic Group Field Theory, posessing a color symmetry, and take the first steps in a systematic study of the topological properties of its graphs. Unlike its bosonic counterpart, the bubbles of the Feynman graphs of this theory are well defined and readily identified. We prove that this graphs are combinatorial cellular complexes. We define and study the cellular homology of this graphs. Furthermore we define a homotopy transformation appropriate to this graphs. Finally, the amplitude of the Feynman graphs is shown to be related to the fundamental group of the cellular complex

Similar works

Full text

Available Versions

Crossref

info:doi/10.1007%2Fs00220-011-...

Last time updated on 02/01/2020