Two-impurity-entanglement generation by electron scattering in zigzag phosphorene nanoribbons

TL;DR

This paper presents a theoretical method for entangling two magnetic impurities in zigzag phosphorene nanoribbons via electron scattering, using Green's function and Lippmann-Schwinger formalism, with potential experimental realizability.

Contribution

It introduces a novel analytical approach to generate entanglement between impurities in phosphorene nanoribbons through electron scattering.

Findings

Analytical expressions for reflected and transmitted wave states.

Calculation of entanglement measure (negativity) in the final state.

Proposed method may be experimentally feasible.

Abstract

In this paper, we investigate how two on-side doped impurities with net magnetic moments in an edge chain of a zigzag phosphorene nanoribbon~(zPNR) can be entangled by scattering of the traveling edge-state electrons. To this end, in the first step, we employ the Lippmann-Schwinger equation as well as the Green's function approach to study the scattering of the free traveling electrons from two magnetic impurities in a one-dimensional tight-binding chain. Then, following the same formalism, that is shown that the behavior of two on-side spin impurities in the edge chain of a zPNR in responding to the scattering of the edge-state traveling electrons is very similar to what happens for the one-dimensional chain. In both cases, considering a known incoming wave state, the reflected and transmitted parts of the final wave state are evaluated analytically. Using the obtained results, the related partial density matrices and the reflection and transmission probabilities are computable. Negativity as a measure of the produced entanglement in the final state is calculated and the results are discussed. Our theoretical model actually proposes a method, which is perhaps experimentally performable to create the entanglement in the state of the impurities.