Cloaking via anomalous localized resonance for doubly complementary media in the finite frequency regime

Abstract

Cloaking a source via anomalous localized resonance (ALR) was discovered by Milton and Nicorovici in [15]. A general setting in which cloaking a source via ALR takes place is the setting of doubly complementary media. This was introduced and studied in [20] for the quasistatic regime. In this paper, we study cloaking a source via ALR for doubly complementary media in the finite frequency regime. To this end, we establish the following results: (1) Cloaking a source via ALR appears if and only if the power blows up; (2) The power blows up if the source is “placed” near the plasmonic structure; (3) The power remains bounded if the source is far away from the plasmonic structure. Concerning the analysis, on one hand we extend ideas from [20] and on the other hand we add new insights into the problem. This allows us to not only overcome difficulties related to the finite frequency regime but to also obtain new information on the problem. In particular, we are able to characterize the behavior of fields far enough from the plasmonic shell, as the loss approaches 0 for an arbitrary source outside the core-shell structure in the doubly complementary media setting.