Highly accurate metamaterial sensor for measurement of permittivity of nanoscale materials

2020 International Conference on UK-China Emerging Technologies (UCET) Pub Date : 2020-08-01 DOI:10.1109/UCET51115.2020.9205481

Abdul Samad, H. Dong, M. Sajid, Waseem Shahzad, Iftikhar Ahmad, M. Nouman

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Abstract

Highly accurate metamaterial sensor for the measurement of permittivity of the nanoscale materials is proposed. The proposed sensor is designed and simulated on low cost substrate FR4 on using ANSYS HFSS simulation software. Two complementary split rectangular resonators (CSRRs) are etched in the ground plane of the sensor in a view to be provided with an accumulative notch depth in transmission coefficient. Single and deep notch in transmission coefficient has significant role in efficient measurement of dielectric properties of the materials under test (MUTs). The effective constitutive parameters (permittivity and permeability) of the proposed sensor are retrieved from scattering parameters. The sensitivity analysis is carried out through the proposed sensor by using the standard materials. The parabolic equation for the proposed sensor is formulated to approximate the relative permittivity of the nanoscale materials. Error analysis is performed to determine the accuracy of the proposed sensor. Very small percentage of error, 0.32, is obtained, which shows high accuracy of the proposed sensor. This methodology is very efficient, low cost and easy in fabrication.

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用于测量纳米尺度材料介电常数的高精度超材料传感器

提出了一种用于测量纳米尺度材料介电常数的高精度超材料传感器。采用ANSYS HFSS仿真软件，在低成本的FR4衬底上对传感器进行了设计和仿真。在传感器的接地面上蚀刻两个互补的分裂矩形谐振器(csrr)，以使其具有传输系数的累积缺口深度。透射系数的单缺口和深缺口对于有效测量被测材料的介电性能具有重要意义。利用散射参数反演传感器的有效本构参数(介电常数和磁导率)。采用标准材料对所设计的传感器进行了灵敏度分析。该传感器的抛物线方程是用来近似纳米尺度材料的相对介电常数。进行误差分析以确定所提出传感器的精度。得到的误差百分比非常小，为0.32，表明该传感器具有很高的精度。该方法效率高，成本低，易于制作。

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2020 International Conference on UK-China Emerging Technologies (UCET)

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