Double-Fano resonance in a two-level quantum system coupled to zigzag Phosphorene nanoribbon

TL;DR

This paper investigates double Fano resonances in a two-level quantum system coupled to zigzag phosphorene nanoribbon edge states, demonstrating controllable interference effects via impurity positioning.

Contribution

It introduces a model of a two-level system coupled to ZPNR edge states and derives an analytical transmission expression showing controllable Fano resonances.

Findings

Double Fano resonances observed in ZPNR with impurity coupling.

Transmission features depend on impurity distance and position.

Analytical expression for transmission coefficient derived.

Abstract

Double-level quantum systems are good candidates for revealing coherent quantum transport properties. Here, we consider quantum interference effects due to the formation of a two-level system (TLS) coupled to the edge channel of a zigzag Phosphorene nanoribbon (ZPNR). Using the tight-binding approach, we first demonstrate the formation of a TLS in bulk Phosphorene sheet due to the existence of two nearby vacancy impurities. Then, we show that such a TLS can couple to the quasi-one-dimensional continuum of the edge states in a ZPNR which results in the the appearance of two-dip Fano-type line shapes. To this end, we generalize the Lippmann-Schwinger approach to study the scattering of edge electrons in a ZPNR by two coupled impurity defects. We obtain an analytical expression of the transmission coefficient which shows that the positions and widths of the anti-resonances can be controlled by changing the intervacancy distance as well as their distance from the edge of the ribbon. This work constitutes a clear example of the multiple Fano resonances in mesoscopic transport.