Metagratings for Perfect Mode Conversion in Rectangular Waveguides: Theory and Experiment

TL;DR

This paper introduces a theoretical and experimental approach using metagratings to achieve perfect mode conversion in rectangular waveguides, offering a simpler alternative to traditional methods.

Contribution

It develops an analytical model for designing passive, lossless metagratings that enable perfect mode conversion inside waveguides, validated by simulations and experiments.

Findings

Achieved perfect TE10 to TE20 mode conversion in waveguides.

Validated the model with full-wave simulations and laboratory measurements.

Provided a fabrication-ready design approach for waveguide mode converters.

Abstract

We present a complete design scheme, from theoretical formulation to experimental validation, exploiting the versatility of metagratings (MGs) for designing a rectangular waveguide (RWG) $\mbox{TE}_{10}$ - $\mbox{TE}_{20}$ mode converter (MC). MG devices, formed by sparse periodically positioned polarizable particles (meta-atoms), were mostly used to date for beam manipulation applications. In this paper, we show that the appealing diffraction engineering features of the MGs in such typical free-space periodic scenarios can be utilized to efficiently mould fields inside waveguides (WGs). In particular, we derive an analytical model allowing harnessing of the MG concept for realization of perfect mode conversion in RWGs. Conveniently, the formalism considers a printed-circuit-board (PCB) MG terminating the RWG, operating as a reflect-mode MC. Following the typical MG synthesis approach, the model directly ties the meta-atom position and geometry with the modal reflection coefficients, enabling resolution of the detailed fabrication-ready design by enforcement of the functionality constraints: elimination of the fundamental $\mbox{TE}_{10}$ reflection and power conservation (passive lossless MG). This reliable semianaltyical scheme, verified via full-wave simulations and laboratory measurements, establishes a simple and efficient alternative to common RWG MCs, typically requiring challenging deformation of the WG designed through time-consuming full-wave optimization. In addition, it highlights the immense potential MGs encompass for a wide variety of applications beyond beam manipulation.