Litcius/Paper detail

Maximized Frequency Doubling through the Inverse Design of Nonlinear Metamaterials

Lakshmi Raju, Kyu‐Tae Lee, Zhaocheng Liu, Dayu Zhu, Muliang Zhu, Ekaterina Poutrina, Augustine Urbas, Wenshan Cai

2022ACS Nano36 citationsDOI

Abstract

The conventional process for developing an optimal design for nonlinear optical responses is based on a trial-and-error approach that is largely inefficient and does not necessarily lead to an ideal result. Deep learning can automate this process and widen the realm of nonlinear geometries and devices. This research illustrates a deep learning framework used to create an optimal plasmonic design for a nonlinear metamaterial. The algorithm produces a plasmonic pattern that can maximize the second-order nonlinear effect of a nonlinear metamaterial. A nanolaminate metamaterial is used as a nonlinear material, and plasmonic patterns are fabricated on the prepared nanolaminate to demonstrate the validity and efficacy of the deep learning algorithm. The optimal pattern produced yielded second-harmonic generation from the nanolaminate with normal incident fundamental light. The deep learning architecture applied in this research can be expanded to other optical responses and light-matter interaction processes.

Topics & Concepts

MetamaterialPlasmonNonlinear systemSecond-harmonic generationComputer scienceDeep learningNanophotonicsNonlinear opticsInverseProcess (computing)Materials scienceOptoelectronicsPhysicsArtificial intelligenceOpticsMathematicsLaserGeometryQuantum mechanicsOperating systemPlasmonic and Surface Plasmon ResearchOptical Wireless Communication TechnologiesMetamaterials and Metasurfaces Applications