NewEvery arXiv paper, its researchers & institutions — mapped.
paper

Quantum Koszul formula on quantum spacetime

arXiv:1707.01481 · doi:10.1016/j.geomphys.2018.02.012

Abstract

Noncommutative or quantum Riemannian geometry has been proposed as an effective theory for aspects of quantum gravity. Here the metric is an invertible bimodule map $Ω^1\otimes_AΩ^1\to A$ where $A$ is a possibly noncommutative or `quantum' spacetime coordinate algebra and $(Ω^1,d)$ is a specified bimodule of 1-forms or `differential calculus' over it. In this paper we explore the proposal of a `quantum Koszul formula' with initial data a degree -2 bilinear map $\perp$ on the full exterior algebra $Ω$ obeying the 4-term relations \[ (-1)^{|η|} (ωη)\perpζ+(ω\perpη)ζ=ω\perp(ηζ)+(-1)^{|ω|+|η|}ω(η\perpζ),\quad\forallω,η,ζ\inΩ\] and a compatible degree -1 `codifferential' map $δ$. These provide a quantum metric and interior product and a canonical bimodule connection $\nabla$ on all degrees. The theory is also more general than classically in that we do not assume symmetry of the metric nor that $δ$ is obtained from the metric. We solve and interpret the $(δ,\perp)$ data on the bicrossproduct model quantum spacetime $[r,t]=λr$ for its two standard choices of $Ω$. For the $α$-family calculus the construction includes the quantum Levi-Civita connection for a general quantum symmetric metric, while for the more standard $β=1$ calculus we find the quantum Levi-Civita connection for a quantum `metric' that in the classical limit is antisymmetric.

39 pages LaTex