Temperature-dependent Goos-Hänchen shifts in a symmetrical graphene-cladding waveguide

Xiang Zhou; Peng Tang; Chenfei Yang; Shuoqing Liu; Zhaoming Luo

Results in Physics (May 2021)

Temperature-dependent Goos-Hänchen shifts in a symmetrical graphene-cladding waveguide

Xiang Zhou,
Peng Tang,
Chenfei Yang,
Shuoqing Liu,
Zhaoming Luo

Affiliations

Xiang Zhou: Key Laboratory of Hunan Province on Information Photonics and Freespace Optical Communications, School of Information Science and Engineering, Hunan Institute of Science and Technology, Yueyang414006, China
Peng Tang: Key Laboratory of Hunan Province on Information Photonics and Freespace Optical Communications, School of Information Science and Engineering, Hunan Institute of Science and Technology, Yueyang414006, China
Chenfei Yang: Key Laboratory of Hunan Province on Information Photonics and Freespace Optical Communications, School of Information Science and Engineering, Hunan Institute of Science and Technology, Yueyang414006, China
Shuoqing Liu: Key Laboratory of Hunan Province on Information Photonics and Freespace Optical Communications, School of Information Science and Engineering, Hunan Institute of Science and Technology, Yueyang414006, China
Zhaoming Luo: Corresponding author.; Key Laboratory of Hunan Province on Information Photonics and Freespace Optical Communications, School of Information Science and Engineering, Hunan Institute of Science and Technology, Yueyang414006, China

Journal volume & issue: Vol. 24
p. 104100

Abstract

Read online

We theoretically investigate the temperature-dependent Goos-Hänchen (GH) shifts in a symmetrical graphene-cladding waveguide (SGCW). The GH shifts in SGCW present a quasi-periodic tendency near the resonance angle with the change of temperature, which can mainly be attributed to the temperature dependence of the guiding layer’s thickness, instead of the graphene intraband conductivity and guiding layer’s refractive index. Importantly, tiny temperature fluctuations can cause significant deviations in GH shifts, and the deviations can be efficiently improved by adjusting the Fermi energy. Therefore, we propose a high-sensitivity temperature sensing scheme based on GH shifts in the SGCW, and the maximum sensitivity can reach up to −2.2 × 105 μm/°C. These researches may open avenues for applications of optical temperature sensors.

Published in Results in Physics

ISSN: 2211-3797 (Online)
Publisher: Elsevier
Country of publisher: Netherlands
LCC subjects: Science: Physics
Website: http://www.journals.elsevier.com/results-in-physics/

About the journal

Abstract

Keywords