IR-truncated PT-symmetric ix3 model and its asymptotic spectral scaling graph

Abstract

The PT-symmetric quantum mechanical V=ix3 model over the real line, x∈R, is infrared (IR) truncated and considered as Sturm-Liouville problem over a finite interval x∈[-L,L]⊂R. Via WKB and Stokes graph analysis, the location of the complex spectral branches of the V=ix3 model and those of more general V=-(ix)2n+1 models over x∈[-L,L]⊂R are obtained. The corresponding eigenvalues are mapped onto L-invariant asymptotic spectral scaling graphs R⊂ C. These scaling graphs are geometrically invariant and cutoff-independent so that the IR limit L ∞ can be formally taken. Moreover, an increasing L can be associated with an R-constrained spectral UV renormalization group flow on R. The existence of a scale-invariant PT symmetry breaking region on each of these graphs allows to conclude that the unbounded eigenvalue sequence of the ix3 Hamiltonian over x∈R can be considered as tending toward a mapped version of such a PT symmetry breaking region at spectral infinity. This provides a simple heuristic explanation for the specific eigenfunction properties described in the literature so far and clear complementary evidence that the PT-symmetric V=-(ix)2n+1 models over the real line x∈R are not equivalent to Hermitian models, but that they rather form a separate model class with purely real spectra. Our findings allow us to hypothesize a possible physical interpretation of the non-Rieszian mode behavior as a related mode condensation process.