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Session 3 Superintegrable Hamiltonians Chairs: Willard Miller Jr. (University of Minnesota, USA) Pavel Winternitz (Universite de Montreal, Canada) Kurt Bernardo Wolf (Universidad Nacional Autonoma de Mexico, Mexico) Titles and Abstracts Cezary Gonera (University of Lodz, Poland) Title: Superintegrability of Hamiltonian systems separable in polar coordinates Abstract: A simple and direct proof of classification of superintegrable systems with Hamiltonians separable in polar coordinates given by E. Onofri and M. Pauri (Journ. Math. Phys. 19 (9) (1978), 1850) is presented. Jonathan Kress (University of New South Wales, Australia) Title: Invariant classification of superintegrable systems Abstract: Superintegrable systems with second order constants of the motion have been extensively studied and all such systems in 3D Euclidean space are known. This talk will present a classification of second order non-degenerate superintegrable systems on 3D conformally flat spaces. It will be shown that each such system is associated with a configuration of 6 points in the extended-complex plane and invariants of these configurations under the action of the conformal group can be used to classify the systems. This is a joint work with Joshua Capel. Willard Miller Jr. (University of Minnesota, USA) Title: Structure theory for extended Kepler-Coulomb 3D quantum superintegrable systems Abstract: A quantum superintegrable system is an integrable n-dimensional Hamiltonian system with potential: H=Delta_n+V that admits 2n-1 algebraically independent partial differential operators commuting with the Hamiltonian, the maximum number possible. The system is of order L if the maximum order of the symmetry operators is L. Typically, the algebra generated by the symmetry operators and their commutators has been proven to close polynomally for n<3 and for systems of order L=2 for general n. However the degenerate 3-parameter potential for the 3D extended Kepler-Coulomb system (2nd order superintegrable) appeared to be an exception as Kalnins et al. (2007) showed that it didn't close polynomially. The 3D 4-parameter potential for the extended Kepler-Coulomb system is not even 2nd order superintegrable. However, Verrier and Evans (2008) showed it was 4th order superintegrable, Tanoudis and Daskaloyannis (2011) showed it closed polynomially. We consider an infinite class of quantum extended Kepler-Coulomb systems that we show to be superintegrable of arbitrarily high order and explain the (apparent) anomalies of these systems. A main conclusion is that rational, nonpolynomial closure, is the expected result for higher order superintegrable systems in n> 2 variables; polynomial closure is very special. Joint work with Ernest Kalnins and Jonathan Kress. George Pogosyan (Yerevan State University, Armenia) Title: Superintegrable systems on SO(2,2) hyperboloids Abstract: The maximal superintegrable systems including the ordinary KeplerCoulomb problem, oscillator and its generalization on SO(2,2) hyperboloid are discussed. Ryu Sasaki (Kyoto University, Japan) Title: Exactly solvable quantum mechanics and Multi-indexed Orthogonal Polynomials Abstract: Multi-indexed orthogonal polynomials are discovered as solutions of exactly solvable 1-d quantum mechanics. They are obtained by multiple Darboux transformations using virtual state solutions. Multiple (q)-Racah polynomials are also reported. Luc Vinet (Université de Montréal, Canada) Title: A superintegrable finite oscillator in two dimensions with SU(2) symmetry Abstract: A superintegrable finite model of the quantum oscillator in two dimensions is introduced. It is defined on a uniform lattice of triangular shape. The constants of the motion for the model form an SU(2) symmetry algebra. The wavefunctions are expressed in terms of bivariate Krawtchouk polynomials. These polynomials form a basis for SU(2) irreducible representations. It is found that the dynamical difference eigenvalue equation can be written in terms of creation and annihilation operators. In the continuous limit, when the number of grid points goes to infinity, standard two-dimensional harmonic oscillators are obtained. The analysis provides the N → ∞ limit of the bivariate Krawtchouk polynomials which is a product of one-variable Hermite polynomials. Based on joint work with H. Miki (Kyoto U.), S. Post (U. Hawai), A. Zhedanov (Donetsk).