From the generalized reflection law to the realization of perfect anomalous reflectors (1609.08041v2)

Abstract: The use of the generalized Snell's law opens wide possibilities for the manipulation of transmitted and reflected wavefronts. However, known structures designed to shape reflection wave fronts suffer from significant parasitic reflections in undesired directions: In fact, the desired field distributions do not satisfy Maxwell's equations if the boundary conditions are specified in accordance with the generalized Snell's law. In this work, we explore the limitations of the existing solutions for the design of passive planar reflectors and demonstrate that strongly non-local response is required for perfect performance. Ideal reflective surfaces capable of steering the energy into any desired direction have to localize and carry energy along the inhomogeneous reflective surface. A new paradigm for the design of perfect reflectors based on energy surface channeling is introduced. We realize and experimentally verify a theoretically perfect design of an anomalously reflective surface using an array of rectangular metal patches backed by a metallic plate. This conceptually new mechanism for wavefront manipulation allows the design of thin perfect reflectors, offering a versatile design method applicable to other scenarios such as focusing reflectors or surface wave manipulations, extendible to other frequencies.