English

Design of efficient high-order immersed metagratings using an evolutionary algorithm

Optics 2026-01-19 v3

Abstract

Immersed reflection gratings improve spectral resolving power by enabling diffraction within a high refractive index medium. This principle has been widely adopted to make grating spectrometers more compact. Conventional immersed gratings have blazed profiles which typically show the highest efficiency for one main design wavelength. In addition, the blazed profiles tend to cause significant polarization sensitivity. In this work, we propose an alternative approach for designing an immersed grating composed of sub-wavelength structures, designed to increase diffraction efficiency and reduce polarization dependence. For a theoretical demonstration, a reflective metagrating immersed in silicon is optimized over the short-wave infrared band-3 (SWIR-3, here 2.304 μ2.304~\mum-2.405 μ2.405~\mum), targeting the same diffraction angles as the immersion grating used in the Sentinel-5 Earth observation mission. The structure is optimized using a modified Covariance Matrix Adaptation Evolution Strategy (CMA-ES). The optimized immersed metagrating achieves an average efficiency of (over the SWIR-3 band) 78%\sim 78\%, compared to 62%\sim 62\% for the conventional immersed blazed grating, and reduces polarization sensitivity from roughly 15%\sim 15\% to 5%\sim 5\%. A manufacturing tolerance analysis is also conducted to evaluate the design's performance under systematic manufacturing errors, which revealed a degradation of 10%\sim 10\% efficiency at feature size errors of ±25nm\pm 25{nm} and almost negligible effect on the efficiency at 10nm-10{nm} and of 5%\sim 5\% at +10nm+10{nm}.

Keywords

Cite

@article{arxiv.2509.21089,
  title  = {Design of efficient high-order immersed metagratings using an evolutionary algorithm},
  author = {Dhwanil Patel and Jacob de Nobel and Anna V. Kononova and Bernhard R. Brandl and Ralf Kohlhaas},
  journal= {arXiv preprint arXiv:2509.21089},
  year   = {2026}
}

Comments

16 pages, 9 figures. published in Optics Express

R2 v1 2026-07-01T05:56:01.277Z