Noncommutative configuration space. Classical and quantum mechanical aspects
Abstract
In this work we examine noncommutativity of position coordinates in classical symplectic mechanics and its quantisation. In coordinates the canonical symplectic two-form is . It is well known in symplectic mechanics {\bf\cite{Souriau,Abraham,Guillemin}} that the interaction of a charged particle with a magnetic field can be described in a Hamiltonian formalism without a choice of a potential. This is done by means of a modified symplectic two-form , where is the charge and the (time-independent) magnetic field is closed: . With this symplectic structure, the canonical momentum variables acquire non-vanishing Poisson brackets: . Similarly a closed two-form in -space may be introduced. Such a {\it dual magnetic field} interacts with the particle's {\it dual charge} . A new modified symplectic two-form is then defined. Now, both - and -variables will cease to Poisson commute and upon quantisation they become noncommuting operators. In the particular case of a linear phase space , it makes sense to consider constant and fields. It is then possible to define, by a linear transformation, global Darboux coordinates: . These can then be quantised in the usual way . The case of a quadratic potential is examined with some detail when equals 2 and 3.
Cite
@article{arxiv.math-ph/0502003,
title = {Noncommutative configuration space. Classical and quantum mechanical aspects},
author = {F. J. Vanhecke and C. Sigaud and A. R. da Silva},
journal= {arXiv preprint arXiv:math-ph/0502003},
year = {2015}
}
Comments
Besides correcting typos, we added a) important references, overlooked in V1, b) a more detailed discussion on the degenerate case, c) a didactical appendix on symplectic reduction