AI Article Synopsis
- Graphene is being utilized for creating flexible and transparent microwave metasurfaces with effective broadband absorption, but its design typically requires extensive parameter adjustments and specialized knowledge.
- Researchers have introduced a machine-learning network capable of predicting reflection spectra and facilitating the inverse design of efficient microwave absorbers, incorporating lightweight and efficient techniques like input normalization and transposed convolution.
- The tunable conductivity of graphene allows for innovative design possibilities, and the machine-learning model shows strong potential in meeting diverse absorption needs for different microwave applications.
Article Abstract
Graphene, as a widely used nanomaterial, has shown great flexibility in designing optically transparent microwave metasurfaces with broadband absorption. However, the design of graphene-based microwave metasurfaces relies on cumbersome parameter sweeping as well as the expertise of researchers. In this paper, we propose a machine-learning network which enables the forward prediction of reflection spectra and inverse design of versatile microwave absorbers. Techniques such as the normalization of input and transposed convolution layers are introduced in the machine-learning network to make the model lightweight and efficient. Particularly, the tunable conductivity of graphene enables a new degree in the intelligent design of metasurfaces. The inverse design system based on the optimization method is proposed for the versatile design of microwave absorbers. Representative cases are demonstrated, showing very promising performances on satisfying various absorption requirements. The proposed machine-learning network has significant potential for the intelligent design of graphene-based metasurfaces for various microwave applications.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9864972 | PMC |
| http://dx.doi.org/10.3390/nano13020329 | DOI Listing |
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