Issue 43, 2019

Chalcogenide–gold dual-layers coupled to gold nanoparticles for reconfigurable perfect absorption

Abstract

Recently, tunable high absorptance from various nanophotonic structures has been demonstrated. However, most of these structures require nano-lithography, which is expensive and slow. Lithography-free tuneable absorbers are rarely explored for tuneable visible and near-infrared photonics. Herein, we demonstrate a gold (Au)/chalcogenide dual-layer that is resonantly coupled to Au nanoparticles (NPs). The structure exhibits angle and polarisation-independent high absorptance. At resonance, waveguide cavity-like modes are excited between the film and NPs whilst gap plasmon modes are excited between the NPs. Coalescence of the waveguide cavity-like modes, the gap plasmon modes, and the highly absorbing chalcogenide semiconductor not only leads to perfect absorptance but also a reconfigurable response via reversible structural phase transitions in the chalcogenide film. In the amorphous state, the design provides nearly perfect absorptance for both p- and s-polarisation states at an incident angle of 20°. However, after switching to the crystalline state, the peak absorptance spectrally broadens and redshifts from 980 to 1520 nm. This experimental observation was theoretically validated by the finite element method. Thermal-electric modeling was performed to show that the structural transition from crystalline to amorphous states is possible in just 5 ns, thus allowing high-speed reconfigurable perfect absorbers.

Graphical abstract: Chalcogenide–gold dual-layers coupled to gold nanoparticles for reconfigurable perfect absorption

Supplementary files

Article information

Article type
Paper
Submitted
05 Jun 2019
Accepted
05 Aug 2019
First published
09 Aug 2019

Nanoscale, 2019,11, 20546-20553

Chalcogenide–gold dual-layers coupled to gold nanoparticles for reconfigurable perfect absorption

T. Cao, K. Liu, L. Lu, H. Chui and R. E. Simpson, Nanoscale, 2019, 11, 20546 DOI: 10.1039/C9NR04759J

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