Weyl quantization
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In mathematics and physics, in the area of quantum mechanics, Weyl quantization is a method for associating a "quantum mechanical" Hermitian operator with a "classical" distribution in phase space. The crucial map from phase-space functions to Hilbert space operators underlying the method was first described by Hermann Weyl in 1927. Formally, however, this map merely amounts to a change of representation, and needs not connect "classical" with "quantum" quantities--the starting phase-space distribution may well depend on Planck's constant , and in some familiar cases involving angular momentum it does.
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[edit] Example
The following demonstrates Weyl quantization on a simple, two-dimensional Euclidean phase space. Let the coordinates on phase space be (q,p) and let f be a function defined everywhere on phase space. The Fourier transform of f is given by
The associated Weyl map operator in Hilbert space is
Here, P and Q are taken to be the generators of a Lie algebra, the Heisenberg algebra:
where is the reduced Planck constant. A general element of the Heisenberg algebra may thus be written as
The exponential map of an element of a Lie algebra is then an element of the corresponding Lie group. Thus,
is an element of the Heisenberg group. Given some particular group representation Φ of the Heisenberg group, the quantity
denotes the element of the representation corresponding to the group element g.
[edit] Properties
Typically, the standard quantum mechanical representation of the Heisenberg group is as a pair of self-adjoint (Hermitian) operators on some Hilbert space , such that the their commutator is the identity on the Hilbert space:
The Hilbert space may taken to be the set of square integrable functions on the real number line (the plane waves), or a more bounded set, such as Schwartz space. Depending on the space, various results follow:
- If f is a real-valued function, then Φ(f) is self-adjoint.
- If f is an element of Schwartz space, then Φ(f) is trace-class.
- More generally, Φ(f) is a densely defined unbounded operator.
- For the standard representation of the Heisenberg group by square integrable functions, the map Φ is one-to-one on the Schwartz space (as a subspace of the square-integrable functions).
[edit] Deformation quantization
In the context of the above flat phase space example, the star product (Moyal product, introduced by Groenewold in 1946) * h of a pair of functions in is specified by
The star product is not commutative in general, but goes over to the ordinary commutative product of functions in the limit of . As such, it is said to define a deformation of the commutative algebra of .
Insofar as the algebra of functions on a space determines the geometry of that space, the study of the star product leads to the study of a non-commutative geometry deformation of that space.
For the Weyl-map example above, the star product may be written in terms of the Poisson bracket as
Here, Π is an operator defined such that its powers are
- Π0(f1,f2) = f1f2
and
where {f1,f2} is the Poisson bracket and, more generally,
where is the binomial coefficient. Antisymmetrization of this star product leads to the Moyal bracket.
[edit] Generalizations
More generally, Weyl quantization is studied in the case where the phase space is a symplectic manifold or possibly a Poisson manifold. Structures include the Poisson-Lie groups and Kac-Moody algebras.
[edit] References
- H.Weyl, "Quantenmechanik und Gruppentheorie", Zeitschrift für Physik, 46 (1927) pp. 1-46.
- H.J. Groenewold, "On the Principles of elementary quantum mechanics",Physica,12 (1946) pp. 405-460.
- J.E. Moyal, "Quantum mechanics as a statistical theory", Proceedings of the Cambridge Philosophical Society, 45 (1949) pp. 99-124.
- F.Bayen, M.Flato, C.Fronsdal, A.Lichnerowicz and D.Sternheimer, "Deformation theory and quantization I, II",Ann. Phys. (N.Y.),111 (1978) pp. 61-110,111-151.
- C. Zachos, D. Fairlie, and T. Curtright, "Quantum Mechanics in Phase Space" ( World Scientific, Singapore, 2005).