English

Finite Quantum Physics and Noncommutative Geometry

High Energy Physics - Theory 2009-10-28 v3 funct-an General Relativity and Quantum Cosmology High Energy Physics - Lattice Functional Analysis

Abstract

Conventional discrete approximations of a manifold do not preserve its nontrivial topological features. In this article we describe an approximation scheme due to Sorkin which reproduces physically important aspects of manifold topology with striking fidelity. The approximating topological spaces in this scheme are partially ordered sets (posets). Now, in ordinary quantum physics on a manifold MM, continuous probability densities generate the commutative C*-algebra \cc(M)\cc(M) of continuous functions on MM. It has a fundamental physical significance, containing the information to reconstruct the topology of MM, and serving to specify the domains of observables like the Hamiltonian. For a poset, the role of this algebra is assumed by a noncommutative C*-algebra \ca\ca . As noncommutative geometries are based on noncommutative C*-algebras, we therefore have a remarkable connection between finite approximations to quantum physics and noncommutative geometries. Various methods for doing quantum physics using \ca\ca are explored. Particular attention is paid to developing numerically viable approximation schemes which at the same time preserve important topological features of continuum physics.

Keywords

Cite

@article{arxiv.hep-th/9403067,
  title  = {Finite Quantum Physics and Noncommutative Geometry},
  author = {A. P. Balachandran and G. Bimonte and E. Ercolessi and G. Landi and F. Lizzi and G. Sparano and P. Teotonio-Sobrinho},
  journal= {arXiv preprint arXiv:hep-th/9403067},
  year   = {2009}
}

Comments

39 pages, 13 figures (small modifications, FIGURES CORRECTED)