Generalized Brewster Angle Effect in Thin-Film Optical Absorbers and Its Application for Graphene Hydrogen Sensing

Overview

Journal ACS Photonics

Publisher American Chemical Society

Date 2019 Jul 30

PMID 31355301

Citations 8

Authors

Kandammathe Valiyaveedu Sreekanth

Mohamed ElKabbash

Rohit Medwal

Jihua Zhang

Theodore Letsou

Giuseppe Strangi

Michael Hinczewski

Rajdeep S Rawat

Chunlei Guo

Ranjan Singh

Affiliations

Soon will be listed here.

Abstract

The generalized Brewster angle (GBA) is the incidence angle at polarization by reflection for p- or s-polarized light. Realizing an s-polarization Brewster effect requires a material with magnetic response, which is challenging at optical frequencies since the magnetic response of materials at these frequencies is extremely weak. Here, we experimentally realize the GBA effect in the visible using a thin-film absorber system consisting of a dielectric film on an absorbing substrate. Polarization by reflection is realized for both p and spolarized light at different angles of incidence and multiple wavelengths. We provide a theoretical framework for the generalized Brewster effect in thin-film light absorbers. We demonstrate hydrogen gas sensing using a single-layer graphene film transferred on a thin-film absorber at the GBA with ∼1 fg/mm aerial mass sensitivity. The ultrahigh sensitivity stems from the strong phase sensitivity near the point of darkness, particularly at the GBA, and the strong light-matter interaction in planar nanocavities. These findings depart from the traditional domain of thin films as mere interference optical coatings and highlight its many potential applications including gas sensing and biosensing.

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