Impact of Stripe Shape on the Reflectivity of Monolithic High Contrast Gratings
Journal article, 2021

Monolithic high contrast gratings (MHCGs) composed of a one-dimensional grating patterned in a monolithic layer provide up to 100% optical power reflectance and can be fabricated in almost any semiconductor and dielectric material used in modern optoelectronics. MHCGs enable monolithic integration, polarization selectivity, and versatile phase tuning. They can be from 10 to 20 times thinner than distributed Bragg reflectors. The subwavelength dimensions of MHCGs significantly reduce the possibility of ensuring the smoothness of the sidewalls of the MHCG stripes and make precise control of the shape of the MHCG stripe cross-section difficult during the etching process. The question is then whether it is more beneficial to improve the etching methods to obtain a perfect cross-section shape, as assumed by the design, or whether it is possible to find geometrical parameters that enable high optical power reflectance using the shape that a given etching method provides. Here, we present a numerical study supported by the experimental characterization of MHCGs fabricated in various materials using a variety of common surface nanometer-scale shaping methods. We demonstrate that MHCG stripes with an arbitrary cross-section shape can provide optical power reflectance of nearly 100%, which greatly relaxes their fabrication requirements. Moreover, we show that optical power reflectance exceeding 99% with a record spectral bandwidth of more than 20% can be achieved for quasi-Trapezoidal cross-sections of MHCGs. We also show that sidewall corrugations of the MHCG stripes have only a slight impact on MHCG optical power reflectance if the amplitude of the corrugation is less than 16% of the MHCG period. This level of stripe fabrication precision can be achieved using the most current surface etching methods. Our results are significant for the design and production of a variety of photonic devices employing MHCGs. The flexibility with regard to cross-section shape facilitates the reliable fabrication of highly reflective subwavelength grating mirrors. This in turn will enable the manufacture of monolithically integrated high-quality-factor optical micro-and nanocavity devices.

optical power reflectance

monolithic high contrast grating

subwavelength grating

Author

Magdalena Marciniak

Lodz University of Technology

Tsung Scheng Chang

National Yang Ming Chiao Tung University

Tien Chang Lu

National Yang Ming Chiao Tung University

Filip Hjort

Chalmers, Microtechnology and Nanoscience (MC2), Photonics

Åsa Haglund

Chalmers, Microtechnology and Nanoscience (MC2), Photonics

Łucja Marona

Polish Academy of Sciences

Matusz Gramala

Nanores Sp. z o.o. Sp. k.

Wrocław University of Science and Technology

Paweł Modrzyński

Nanores Sp. z o.o. Sp. k.

Wrocław University of Science and Technology

R Kudrawiec

Wrocław University of Science and Technology

Krzysztof Sawicki

University of Warsaw

Rafał Bożek

University of Warsaw

Wojciech Pacuski

University of Warsaw

Jan Suffczyński

University of Warsaw

M. Gebski

Lodz University of Technology

Artur Broda

Warsaw University of Technology

Jan Muszalski

Warsaw University of Technology

James A. Lott

Technische Universität Berlin

Tomasz Czyszanowski

Lodz University of Technology

ACS Photonics

2330-4022 (eISSN)

Vol. 8 11 3173-3184

Subject Categories

Atom and Molecular Physics and Optics

Other Physics Topics

Other Electrical Engineering, Electronic Engineering, Information Engineering

DOI

10.1021/acsphotonics.1c00850

More information

Latest update

4/5/2022 5