Abstract
The question how to quantize a classical system where an angle is one of the basic canonical variables has been controversial since the early days of quantum mechanics. The problem is that the angle is a multivalued or discontinuous variable on the corresponding phase space. The remedy is to replace by the smooth periodic functions and . In the case of the canonical pair , where is the orbital angular momentum (OAM), the phase space has the global topological structure of a cylinder on which the Poisson brackets of the three functions , and obey the Lie algebra of the Euclidean group in the plane. This property provides the basis for the quantization of the system in terms of irreducible unitary representations of the group or of its covering groups. A crucial point is that, due to the fact that the subgroup is multiply connected, these representations allow for fractional OAM . Such have already been observed in cases like the Aharonov-Bohm and fractional quantum Hall effects, and they correspond to the quasimomenta of Bloch waves in ideal crystals. The proposal of the present paper is to look for fractional OAM in connection with the quantum optics of Laguerre-Gaussian laser modes in external magnetic fields. The quantum theory of the phase space in terms of unitary representations of allows for two types of “coherent” states, the properties of which are discussed in detail: nonholomorphic minimal-uncertainty states and holomorphic ones associated with Bargmann-Segal Hilbert spaces.
- Received 21 November 2005
DOI:https://doi.org/10.1103/PhysRevA.73.052104
©2006 American Physical Society