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Covariant Quantum Fields on Noncommutative Spacetimes

High Energy Physics - Theory 2011-04-04 v1 General Relativity and Quantum Cosmology Mathematical Physics math.MP Quantum Algebra

Abstract

A spinless covariant field ϕ\phi on Minkowski spacetime \Md+1\M^{d+1} obeys the relation U(a,Λ)ϕ(x)U(a,Λ)1=ϕ(Λx+a)U(a,\Lambda)\phi(x)U(a,\Lambda)^{-1}=\phi(\Lambda x+a) where (a,Λ)(a,\Lambda) is an element of the Poincar\'e group \Pg\Pg and U:(a,Λ)U(a,Λ)U:(a,\Lambda)\to U(a,\Lambda) is its unitary representation on quantum vector states. It expresses the fact that Poincar\'e transformations are being unitary implemented. It has a classical analogy where field covariance shows that Poincar\'e transformations are canonically implemented. Covariance is self-reproducing: products of covariant fields are covariant. We recall these properties and use them to formulate the notion of covariant quantum fields on noncommutative spacetimes. In this way all our earlier results on dressing, statistics, etc. for Moyal spacetimes are derived transparently. For the Voros algebra, covariance and the *-operation are in conflict so that there are no covariant Voros fields compatible with *, a result we found earlier. The notion of Drinfel'd twist underlying much of the preceding discussion is extended to discrete abelian and nonabelian groups such as the mapping class groups of topological geons. For twists involving nonabelian groups the emergent spacetimes are nonassociative.

Keywords

Cite

@article{arxiv.1009.5136,
  title  = {Covariant Quantum Fields on Noncommutative Spacetimes},
  author = {A. P. Balachandran and A. Ibort and G. Marmo and M. Martone},
  journal= {arXiv preprint arXiv:1009.5136},
  year   = {2011}
}

Comments

20 pages

R2 v1 2026-06-21T16:19:15.627Z