Quantum mechanics without spacetime: a case for noncommutative geometry
Abstract
Quantum mechanics in its presently known formulation requires an external classical time for its description. A classical spacetime manifold and a classical spacetime metric are produced by classical matter fields. In the absence of such classical matter fields, quantum mechanics should be formulated without reference to a classical time. If such a new formulation exists, it follows as a consequence that standard linear quantum mechanics is a limiting case of an underlying non-linear quantum theory. A possible approach to the new formulation is through the use of noncommuting spacetime coordinates in noncommutative differential geometry. Here, the non-linear theory is described by a non-linear Schrodinger equation which belongs to the Doebner-Goldin class of equations, discovered some years ago. This mass-dependent non-linearity is significant when particle masses are comparable to Planck mass, and negligible otherwise. Such a non-linearity is in principle detectable through experimental tests of quantum mechanics for mesoscopic systems, and is a valuable empirical probe of theories of quantum gravity. We also briefly remark on the possible connection our approach could have with loop quantum gravity and string theory.
Cite
@article{arxiv.gr-qc/0510042,
title = {Quantum mechanics without spacetime: a case for noncommutative geometry},
author = {T. P. Singh},
journal= {arXiv preprint arXiv:gr-qc/0510042},
year = {2008}
}
Comments
35 pages, based on an invited talk given at QTS-4 [Fourth International Conference on Quantum Theory and Symmetries], Varna, Bulgaria, 15-21 August, 2005