English

Noncommutative configuration space. Classical and quantum mechanical aspects

Mathematical Physics 2015-06-26 v2 High Energy Physics - Theory math.MP

Abstract

In this work we examine noncommutativity of position coordinates in classical symplectic mechanics and its quantisation. In coordinates {qi,pk}\{q^i,p_k\} the canonical symplectic two-form is ω0=dqidpi\omega_0=dq^i\wedge dp_i. 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 ω=ω0e\F\omega=\omega_0-e\F, where ee is the charge and the (time-independent) magnetic field \F\F is closed: \dif\F=0\dif\F=0. With this symplectic structure, the canonical momentum variables acquire non-vanishing Poisson brackets: {pk,pl}=eFkl(q)\{p_k,p_l\} = e F_{kl}(q). Similarly a closed two-form in pp-space \G\G may be introduced. Such a {\it dual magnetic field} \G\G interacts with the particle's {\it dual charge} rr. A new modified symplectic two-form ω=ω0e\F+r\G\omega=\omega_0-e\F+r\G is then defined. Now, both pp- and qq-variables will cease to Poisson commute and upon quantisation they become noncommuting operators. In the particular case of a linear phase space R2N{\bf R}^{2N}, it makes sense to consider constant \F\F and \G\G fields. It is then possible to define, by a linear transformation, global Darboux coordinates: {ξi,πk}=δik\{\xi^i,\pi_k\}= {\delta^i}_k. These can then be quantised in the usual way [ξ^i,π^k]=iδik[\hat{\xi}^i,\hat{\pi}_k]=i\hbar {\delta^i}_k. The case of a quadratic potential is examined with some detail when NN equals 2 and 3.

Keywords

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