Three types of discrete energy eigenvalues in complex PT-symmetric scattering potentials

Abstract

For complex PT-symmetric scattering potentials (CPTSSPs) V(x)= V1 feven(x) + iV2 fodd(x), feven( ∞) = 0 = fodd( ∞), V1,V2 ∈ , we show that complex k-poles of transmission amplitude t(k) or zeros of 1/t(k) of the type k1+ik2, k2 0 are physical which yield three types of discrete energy eigenvalues of the potential. These discrete energies are real negative, complex conjugate pair(s) of eigenvalues (CCPEs: En i γn) and real positive energy called spectral singularity (SS) at E=E* where the transmission and reflection co-efficient of V(x) become infinite for a special critical value of V2=V*. Based on four analytically solvable and other numerically solved models, we conjecture that a parametrically fixed CPTSSP has at most one SS. When V1 is fixed and V2 is varied there may exist Kato's exceptional point(s) (VEP) and critical values V*m, m=0,1,2,.., so when V2 crosses one of these special values a new CCPE is created. When V2 equals a critical value V*m there exist one SS at E=E* along with m or more number of CCPEs. Hence, this single positive energy E* is the upper (or rough upper) bound to the CCPEs: El E*, here El corresponds to the last of CCPEs. If V(x) has Kato's exceptional points (EPs: VEP1<VEP2<VEP3<...<VEPl), the smallest of critical values V*m is always larger than VEPl. Hence, in a CPTSSP, real discrete eigenvalue(s) and the SS are mutually exclusive whereas CCPEs and the SS can co-exist .