Computation and Modeling of Microwave Absorbing Cuo/Graphene Nanocomposites

Abstract

In this study, the microwave absorption properties of single- and double-layer composites were investigated for experimental and numerical solution in the 8.2 to 12.4 GHz for different thickness (t(m)) of composites. Herein, the single-layer composites (R1: CuO and R2: CuO-containing graphene nanoparticle [GNP]) and double-layer composites that composed of R1 and R2 layers were fabricated. The first double-layer composite labeled as D1 contains R1 as a matching layer and R2 as an absorbing layer and the second double-layer composite labeled as D2 contains R2 as a matching layer and R1 as an absorbing layer. D1 and D2 produced composites were also designed numerically and denoted as M1 and M2, respectively. The measured and simulated reflection loss (R-L) of double-layer composites shows similar performance, and it was observed that the microwave absorbers obtained with experimental studies can be modeled using computer design. The M2 double-layer design based on 5 mm of the matching layer and 2 mm of the absorbing layer shows a minimum R-L value of -33.7 dB at 10.06 GHz and an absorption bandwidth of about 1.13 GHz below -10 dB compared to single-layer composites.