A novel design of THz resonance gas sensor with advanced 2-bit encoding capabilities

This study presents a terahertz (THz) resonance gas sensor design incorporating graphene, black phosphorus, and MXene materials in a metasurface structure. The sensor leverages the unique properties of these advanced two-dimensional materials to achieve enhanced sensitivity and versatility in gas detection applications. The proposed design consists of elliptical and square-shaped resonators arranged on a SiO₂ substrate with a ground plane back reflector. Comprehensive simulations using COMSOL Multiphysics were conducted to analyze the sensor’s performance across various structural parameters and operating conditions. The sensor demonstrates a maximum sensitivity of 400 GHzRIU⁻¹ and a figure of merit up to 0.816 RIU⁻¹ within a refractive index range of 1–1.07 RIU. Electric field distribution analysis validates the sensor’s transmittance response at different frequencies. Notably, the design shows potential for 2-bit encoding applications based on transmittance characteristics under varying graphene chemical potential values. Compared to existing studies, the senso’s performance is particularly better in terms of sensitivity, offering advantages such as room temperature operation and fast response times. This research contributes to the advancement of THz sensing technology and opens new possibilities for highly sensitive and versatile gas detection in various applications.