Frequency-doubling perfect negative reflection in phase gradient metasurfaces

Abstract

Phase gradient metasurfaces (PGMs) have demonstrated powerful capacities for manipulating light waves freely. However, PGMs have limitations of bulky size and narrow bandwidth that hinder further applications. In this work, we present the design and analysis of a reflection-type PGM by utilizing the phase choice freedom in the supercell. It is found that in this well-designed PGM, perfect negative reflection including perfect retro-reflection can be observed not only at the initially designed frequency f1 = f0, but also at its double frequency, i.e., f2 = 2f0, which is named as the frequency-doubling perfect negative reflection. As a proof of concept, we design and fabricate a reflection-type PGM with 4π phase coverage in a supercell, with experimental results in perfect agreement with the theoretical ones. Our work offers an approach to design planar optical devices at multiple operating frequencies, holding potential applications for frequency division multiplexing communication, remote sensor technology, laser tracking, and more.