Surface Electromagnetic Performance Analysis of a Graphene-Based Terahertz Sensor Using a Novel Spectroscopy Technique

摘要

In this paper, a novel terahertz (THz) spectroscopy technique and a new graphene-based sensor is proposed. The proposed sensor consists of a graphene-based metasurface (MS) that operates in reflection mode over a broad range of frequency band (0.2 – 6 THz) and can detect relative permittivity of up to 4 with a resolution of 0.1 and a thickness ranging from 5 amp;inline-formulaamp; amp;tex-math notation="LaTeX"amp;$mu text{m}$ amp;/tex-mathamp;amp;/inline-formulaamp; to 600 amp;inline-formulaamp; amp;tex-math notation="LaTeX"amp;$mu text{m}$ amp;/tex-mathamp;amp;/inline-formulaamp; with a resolution of 0.5 amp;inline-formulaamp; amp;tex-math notation="LaTeX"amp;$mu text{m}$ amp;/tex-mathamp;amp;/inline-formulaamp;. To the best of author’s knowledge, such a THz sensor with such capabilities has not been reported yet. Additionally, an equivalent circuit of the novel unit cell is derived and compared with two conventional grooved structures to showcase the superiority of the proposed unit cell. The proposed spectroscopy technique utilizes some unique spectral features of a broadband reflection wave including Accumulated Spectral power (ASP) and Averaged Group Delay (AGD), which are independent to resonance frequencies and can operate over a broad range of spectrum. ASP and AGD can be combined to analyse the magnitude and phase of the reflection diagram as a coherent technique for sensing purposes. This enables the capability to distinguish between different analytes with high precision which, to the best of author’s knowledge, has been accomplished for the first time.