Entropic characterization of Tunneling and State Pairing in a Quasi-Exactly Solvable Sextic Potential

Abstract

We analyze the (de)localization properties of a quasi-exactly solvable (QES) sextic potential VQES(x) = 12(x6 + 2x4 - 2(2λ + 1)x2) as a function of the tunable parameter λ ∈ [-34, 6]. For λ > -12, the potential exhibits a symmetric double-well structure, with tunneling emerging for the ground state level at λ ≈ 0.732953. For the lowest energy states \( n = 0,1,2,3 \), we construct physically meaningful variational wavefunctions that i) respect parity symmetry under the transformation x → -x, ii) exhibit the correct asymptotic behavior at large distances, and iii) allow for exact analytical Fourier transforms. Variational energies match Lagrange Mesh and available exact analytical QES results with relative errors 10-8 for n = 0, 1, 2 and 10-6 for the third excited state n=3. We demonstrate that entropic measures (Shannon entropy, Kullback-Leibler, and Cumulative Residual Jeffreys divergences) surpass conventional variance-based methods in revealing tunneling transitions, wavefunction symmetry breaking, and quantum state pairing. Our results confirm that the Beckner-Bialynicki-Birula-Mycielski entropic uncertainty relation holds across all examined values of n and λ. The quality of the trial function is also validated by the small 10-10 Cumulative Residual Jeffreys divergences from the exact QES solutions.