Control of Extraordinary Optical Transmission in Resonant Terahertz Gratings via Lateral Depletion in an AlGaN-GaN Heterostructure

TL;DR

This paper demonstrates dynamic control of extraordinary optical transmission in terahertz gratings by modulating charge density in an AlGaN-GaN heterostructure, enabling tunable electromagnetic resonance effects.

Contribution

It introduces a method to actively manipulate terahertz optical transmission via lateral depletion of a 2DEG in a patterned heterostructure, revealing new insights into carrier-resonance interactions.

Findings

Depletion of 2DEG enhances coupling to substrate resonances.

Charge distribution critically affects guided-mode resonance.

Dynamic modulation of terahertz transmission achieved.

Abstract

Periodic metallic gratings on substrates can support a range of electromagnetic modes, such as leaky waveguide, guided-resonant, and Fabry-Perot (FP) cavity modes, which can strongly modulate optical transmission under resonant excitation. Here, we investigate how this coupling can be dynamically manipulated through charge-density control in a laterally patterned AlGaN/GaN heterostructure. The structure comprises metallic stripes separated by regions containing a two-dimensional electron gas (2DEG), forming a periodically modulated interface whose electromagnetic response is governed by the charge density between the stripes. In the unbiased state, the conductive 2DEG screens the incident terahertz field and suppresses excitation of guided modes. When the 2DEG is depleted, the change in boundary conditions allows efficient coupling into substrate resonances, producing a strong modulation at particular frequencies where extraordinary optical transmission (EOT) through the structure takes place. The results highlight the sensitive dependence of guided-mode-resonance (GMR) mediated EOT on inter-stripe charge distribution and demonstrate a direct interplay between carrier dynamics and resonant electromagnetic phenomena in the terahertz regime.