Exploiting deep learning network in optical chirality tuning and manipulation of diffractive chiral metamaterials

Exploiting deep learning network in optical chirality tuning and manipulation of diffractive chiral metamaterials

Deep-learning (DL) network has emerged as an important prototyping technology for the advancements of big data analytics, intelligent systems, biochemistry, physics, and nanoscience. Here, we used a DL model whose key algorithm relies on deep neural network to efficiently predict circular dichroism...

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Bibliographic Details
Published in:Nanophotonics (Berlin, Germany) Vol. 9; no. 9; pp. 2945 - 2956
Main Authors: Tao, Zilong, Zhang, Jun, You, Jie, Hao, Hao, Ouyang, Hao, Yan, Qiuquan, Du, Shiyin, Zhao, Zeyu, Yang, Qirui, Zheng, Xin, Jiang, Tian
Format: Journal Article
Language:English
Published: Berlin De Gruyter 01-09-2020
Walter de Gruyter GmbH
Subjects:
Accuracy
Algorithms
Artificial neural networks
Chirality
circular dichroism
Deep learning
deep learning neural networks
Design optimization
Dichroism
Diffraction
diffractive chiral metamaterials
Geometry
Interdisciplinary aspects
Investigations
Machine learning
Metamaterials
Neural networks
optical chirality
Parameters
Physics
polarization-selective devices
Prototyping
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Summary:Deep-learning (DL) network has emerged as an important prototyping technology for the advancements of big data analytics, intelligent systems, biochemistry, physics, and nanoscience. Here, we used a DL model whose key algorithm relies on deep neural network to efficiently predict circular dichroism (CD) response in higher-order diffracted beams of two-dimensional chiral metamaterials with different parameters. To facilitate the training process of DL network in predicting chiroptical response, the traditional rigorous coupled wave analysis (RCWA) method is utilized. Notably, these T-like shaped chiral metamaterials all exhibit the strongest CD response in the third-order diffracted beams whose intensities are the smallest, when comparing up to four diffraction orders. Our comprehensive results reveal that by means of DL network, the complex and nonintuitive relations between T-like metamaterials with different chiral parameters (i. e., unit period, width, bridge length, and separation length) and their CD performances are acquired, which owns an ultrafast computational speed that is four orders of magnitude faster than RCWA and a high accuracy. The insights gained from this study may be of assistance to the applications of DL network in investigating different optical chirality in low-dimensional metamaterials and expediting the design and optimization processes for hyper-sensitive ultrathin devices and systems.
ISSN:2192-8606
2192-8614
DOI:10.1515/nanoph-2020-0194