Bernoulli, Euler, permutations and quantum algebras
Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 463:2086 (2007) 2401-2414
Abstract:
The combinatorial properties of the Bernoulli and Euler numbers are interpreted using a new classification of permutations. The classification is naturally described by an operator algebra of a type familiar from quantum theory. It has a duality structure described by an operator satisfying anticommutation relations. © 2007 The Royal Society.Quantum algebras and parity-dependent spectra
Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 463:2086 (2007) 2415-2427
Abstract:
We study the structure of a quantum algebra in which a parity-violating term modifies the standard commutation relation between the creation and annihilation operators of the simple harmonic oscillator. We discuss several useful applications of the modified algebra. We show that the Bernoulli and Euler numbers arise naturally in a special case. We also show a connection with Gaussian and non-Gaussian squeezed states of the simple harmonic oscillator. Such states have been considered in quantum optics. The combinatorial theory of Bernoulli and Euler numbers is developed and used to calculate matrix elements for squeezed states. © 2007 The Royal Society.Sum rules for Confining Potentials
ArXiv quant-ph/0611066 (2006)
Abstract:
Using the Green's function associated with the one-dimensional Schroedinger equation it is possible to establish a hierarchy of sum rules involving the eigenvalues of confining potentials which have only a boundstate spectrum. For some potentials the sum rules could lead to divergences. It is shown that when this happens it is possible to examine the separate sum rules satisfied by the even and odd eigenstates of a symmetric confining potential and by subtraction cancel the divergences exactly and produce a new sum rule which is free of divergences. The procedure is illustrated by considering symmetric power law potentials and the use of several examples. One of the examples considered shows that the zeros of the Airy function and its derivative obey a sum rule and this sum rule is verified. It is also shown how the procedure may be generalised to establish sum rules for arbitrary symmetric confining potentials.Phase equivalent potentials, complex coordinates and supersymmetric quantum mechanics
Journal of Physics A: Mathematical and General 39 (2006) 14499-14509
Sum rules and the domain after the last node of an eigenstate
Journal of Physics A: Mathematical and General 39 (2006) 14153-14163