Abstract
Terahertz wave has attracted significant attention in recent years, and terahertz devices have been applied in various fields. However, the complicated and time-consuming spectrum prediction and structure design issues have hindered the widespread application of terahertz science. In this work, we propose a new method to use neural networks to predict the reflection spectrum in the terahertz band, and more importantly, design a micro-nano structure with an on-demand optical response. To verify the effectiveness, we select a terahertz metasurface as an example for discussion. After the neural networks are trained, the spectrum prediction can achieve high precision, and the neural network also has encouraging performance when solving the design problem of micro-nano structure. Furthermore, we conclude that we can choose structure design neural networks with different complexity to satisfy different demands, and can optimize the networks to improve accuracy. Our work demonstrates that such a data-driven neural network can be applied to study the prediction and design problem of metasurface in the terahertz band and provide more opportunities for the terahertz devices in the future.
Highlights
Terahertz (THz) wave refers to the electromagnetic wave with the frequency range of 0.1–10 THz
The complicated and time-consuming spectrum prediction and structure design issues have hindered the widespread application of terahertz science
Our work demonstrates that such a data-driven neural network can be applied to study the prediction and design problem of metasurface in the terahertz band and provide more opportunities for the terahertz devices in the future
Summary
Terahertz (THz) wave refers to the electromagnetic wave with the frequency range of 0.1–10 THz. One challenge is how to effectively predict the spectrum for a given micro-nano structure, while another rougher challenge is how to design a micro-nano structure based on the on-demand spectrum The former is referred to as forward prediction, and the latter is known as inverse design, which has gained wide attention and great achievements [11]–[13] recently. Typical methods for the inverse design are genetic algorithm and adjoint method [15], [16], both of which require vast trial and error with the increasing complexity of micro-nano structure These issues hinder the widespread application of THz science. We propose a novel method to use NNs to achieve THz spectrum prediction and inverse design and explore its performance
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