An exactly solvable quantum-lattice model with a tunable degree of nonlocality

Abstract

An array of N subsequent Laguerre polynomials is interpreted as an eigenvector of a non-Hermitian tridiagonal Hamiltonian H with real spectrum or, better said, of an exactly solvable N-site-lattice cryptohermitian Hamiltonian whose spectrum is known as equal to the set of zeros of the N-th Laguerre polynomial. The two key problems (viz., the one of the ambiguity and the one of the closed-form construction of all of the eligible inner products which make H Hermitian in the respective ad hoc Hilbert spaces) are discussed. Then, for illustration, the first four simplest, k-parametric definitions of inner products with k=0,k=1,k=2 and k=3 are explicitly displayed. In mathematical terms these alternative inner products may be perceived as alternative Hermitian conjugations of the initial N-plet of Laguerre polynomials. In physical terms the parameter k may be interpreted as a measure of the "smearing of the lattice coordinates" in the model.