English

Efficient silicon metasurfaces for visible light

Optics 2017-02-15 v1

Abstract

Dielectric metasurfaces require high refractive index contrast materials for optimum performance. This requirement imposes a severe restraint; devices have either been demonstrated at wavelengths of 700nm and above using high-index semiconductors such as silicon, or they use lower index dielectric materials such as TiO2_{2} or Si3_{3}N4_{4} and operate in the visible wavelength regime. Here, we show that the high refractive index of silicon can be exploited at wavelengths as short as 532 nm by demonstrating a silicon metasurface with a transmission efficiency of 47% at this wavelength. The metasurface consists of a graded array of silicon posts arranged in a square lattice on a quartz substrate. We show full 2{\pi} phase control and we experimentally demonstrate polarization-independent beam deflection at 532nm wavelength. The crystalline silicon is placed on a quartz substrate by a bespoke layer transfer technique and we note that an efficiency >70% may be achieved for a further optimized structure in the same material. Our results open a new way for realizing efficient metasurfaces based on silicon in the visible wavelength regime.

Keywords

Cite

@article{arxiv.1609.06400,
  title  = {Efficient silicon metasurfaces for visible light},
  author = {Zhenpeng Zhou and Juntao Li and Rongbin Su and Beimeng Yao and Hanlin Fang and Kezheng Li and Lidan Zhou and Jin Liu and Daan Stellinga and Christopher P Reardon and Thomas F Krauss and Xuehua Wang},
  journal= {arXiv preprint arXiv:1609.06400},
  year   = {2017}
}

Comments

16 pages, 6 figures, 2 tables

R2 v1 2026-06-22T15:56:07.545Z