Contraction of broken symmetries via Kac-Moody formalism
Abstract
I investigate contractions via Kac-Moody formalism. In particular, I show how the symmetry algebra of the standard 2-D Kepler system, which was identified by Daboul and Slodowy as an infinite-dimensional Kac-Moody loop algebra, and was denoted by H2 , gets reduced by the symmetry breaking term, defined by the Hamiltonian \[ H(β)= 1 2m (p12+p22)- α r - β r-1/2 ((φ-γ)/2). \] For this H (β) I define two symmetry loop algebras Li(β), i=1,2, by choosing the `basic generators' differently. These Li(β) can be mapped isomorphically onto subalgebras of H2 , of codimension 2 or 3, revealing the reduction of symmetry. Both factor algebras Li(β)/Ii(E,β), relative to the corresponding energy-dependent ideals Ii(E,β), are isomorphic to so(3) and so(2,1) for E<0 and E>0, respectively, just as for the pure Kepler case. However, they yield two different non-standard contractions as E 0, namely to the Heisenberg-Weyl algebra h3= w1 or to an abelian Lie algebra, instead of the Euclidean algebra e(2) for the pure Kepler case. The above example suggests a general procedure for defining generalized contractions, and also illustrates the `deformation contraction hysteresis', where contraction which involve two contraction parameters can yield different contracted algebras, if the limits are carried out in different order.
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