The SUSY partners of the QES sextic potential revisited

Abstract

In this paper, the SUSY partner Hamiltonians of the quasi-exactly solvable (QES) sextic potential V qes(x) = \, x6 + 2\, \, μ\,x4 + [μ2-(4N+3) ]\, x2, N ∈ Z+, are revisited from a Lie algebraic perspective. It is demonstrated that, in the variable τ=x2, the underlying sl2(R) hidden algebra of V qes(x) is inherited by its SUSY partner potential V1(x) only for N=0. At fixed N>0, the algebraic polynomial operator h(x,\,∂x;\,N) that governs the N exact eigenpolynomial solutions of V1 is derived explicitly. These odd-parity solutions appear in the form of zero modes. The potential V1 can be represented as the sum of a polynomial and rational parts. In particular, it is shown that the polynomial component is given by V qes with a different non-integer (cohomology) parameter N1=N-32. A confluent second-order SUSY transformation is also implemented for a modified QES sextic potential possessing the energy reflection symmetry. By taking N as a continuous real constant and using the Lagrange-mesh method, highly accurate values ( 20 s. d.) of the energy En=En(N) in the interval N ∈ [-1,3] are calculated for the three lowest states n=0,1,2 of the system. The critical value Nc above which tunneling effects (instanton-like terms) can occur is obtained as well. At N=0, the non-algebraic sector of the spectrum of V qes is described by means of compact physically relevant trial functions. These solutions allow us to determine the effects in accuracy when the first-order SUSY approach is applied on the level of approximate eigenfunctions.

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