Coalescence of Anderson-localized modes at an exceptional point in 2D random media
Nicolas Bachelard, Carlos Garay, Julien Arlandis, Rachid Touzani and, Patrick Sebbah
TL;DR
This paper develops a non-perturbative theory to predict the occurrence of exceptional points where Anderson-localized modes coalesce in 2D disordered photonic systems, with implications for experimental observation.
Contribution
It introduces a new theoretical framework for predicting exceptional points in 2D open dielectric systems with disorder.
Findings
Theory accurately predicts exceptional points between localized states.
Prediction accuracy improves with more localized states considered.
Experimental realization in disordered photonic systems is feasible.
Abstract
In non-hermitian systems, the particular position at which two eigenstates coalesce under a variation of a parameter in the complex plane is called an exceptional point. A non-perturbative theory is proposed which describes the evolution of modes in 2D open dielectric systems when permittivity distribution is modified. We successfully test this theory in a 2D disordered system to predict the position in the parameter space of the exceptional point between two Anderson-localized states. We observe that the accuracy of the prediction depends on the number of localized states accounted for. Such an exceptional point is experimentally accessible in practically relevant disordered photonic systems
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