Further fundamental bounds on the Hall effect in three-dimensional metamaterials

Abstract We consider the problem of bounding the effective non-reciprocal properties of metamaterials. Recently, significant progress was made by showing that this problem can be reduced to bounding an equivalent reciprocal one and applying a monotonicity argument. Here, we build upon this result and provide bounds incorporating additional information about the metamaterial. Specifically, in the two-phase case, we provide bounds for isotropic metamaterials. In the multi-phase case, we provide bounds for uniaxial metamaterials that additionally incorporate the volume fractions. In both instances, the incorporated additional information significantly tightens the bounds. In the two-phase case, we evaluate the bounds by comparing them to the effective properties of hierarchical laminate microstructures. This comparison ultimately leads us to propose a set of conjectured bounds. While our discussion focuses on the Hall effect, our results are more broadly applicable to other non-reciprocal effects in so far as their mathematical description is equivalent. In particular, our bounds apply to the Faraday effect in the quasistatic regime and in the absence of losses and resonances.