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arxiv: 2312.16330 · v1 · pith:C2P5MSZI · submitted 2023-12-26 · physics.optics · cond-mat.mes-hall· physics.app-ph

Achieving 100% amplitude modulation depth in a graphene-based tuneable capacitance metamaterial

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classification physics.optics cond-mat.mes-hallphysics.app-ph
keywords modulationdepthgrapheneterahertzmetamaterialamplitudeeffectivemodulator
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Effective control of terahertz radiation requires the development of efficient and fast modulators with a large modulation depth. This challenge is often tackled by using metamaterials, artificial sub-wavelength optical structures engineered to resonate at the desired terahertz frequency. Metamaterial-based devices exploiting graphene as the active tuneable element have been proven to be a highly effective solution for THz modulation. However, whilst the graphene conductivity can be tuned over a wide range, it cannot be reduced to zero due to the gapless nature of graphene, which directly limits the maximum achievable modulation depth for single-layer metamaterial modulators. Here, we demonstrate two novel solutions to circumvent this restriction: Firstly, we excite the modulator from the back of the substrate, and secondly, we incorporate air gaps into the graphene patches. This results in a ground-breaking graphene-metal metamaterial terahertz modulator, operating at 2.0-2.5 THz, which demonstrates a 99.01 % amplitude and a 99.99 % intensity modulation depth at 2.15 THz, with a reconfiguration speed in excess of 3 MHz. Our results open up new frontiers in the area of terahertz technology.

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