Abstract

We studied the scattering state behavior of tight-binding quantum system and classical electrical transmission lines. We distributed on-site energies ϵ n and resistances R n , respectively, according to a parity-time -symmetric distribution. Using the formalism of scattering matrix S and transfer matrix M, we derived analytical expressions for components of transfer matrix M, and through them, we found transmission coefficient T and left (R L ) and right (R R ) reflectance. In addition, we found a generalized conservation relation that relates T, R L and R R , valid for quantum and classical -symmetric systems. We numerically studied the general behavior of T, R L , R R and eigenvalues s ± of scattering matrix S in the full range of possible values of the gain and loss parameters. We observed the existence of unidirectional and bidirectional transparency for specific energies E (quantum case) and specific frequencies Ω (transmission line case), for which the following conditions were simultaneously fulfilled: i) T was unitary (T = 1), ii) eigenvalues s ± were degenerate and unimodular , iii) the product of reflectances tended to zero, , and iv) phases ϕ of one or both reflection amplitudes showed abrupt change of π. This way, we characterized the unidirectional and bidirectional transparency for classical and quantum systems as a function of the gain and loss parameters that describe both models. In addition, the theoretical results showed complete agreement with the numerical calculation. We hope that our work contributes to a better understanding of the influence of the -symmetric distribution of gain and loss parameters on the scattering properties of quantum and classical systems.

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