Litcius/Paper detail

Prediction and Inverse Design of Structural Colors of Nanoparticle Systems via Deep Neural Network

Lanxin Ma, Kaixiang Hu, Chengchao Wang, Jia‐Yue Yang, Linhua Liu

2021Nanomaterials17 citationsDOIOpen Access PDF

Abstract

Noniridescent and nonfading structural colors generated from metallic and dielectric nanoparticles with extraordinary optical properties hold great promise in applications such as image display, color printing, and information security. Yet, due to the strong wavelength dependence of optical constants and the radiation pattern, it is difficult and time-consuming to design nanoparticles with the desired hue, saturation, and brightness. Herein, we combined the Monte Carlo and Mie scattering simulations and a bidirectional neural network (BNN) to improve the design of gold nanoparticles' structural colors. The optical simulations provided a dataset including color properties and geometric parameters of gold nanoparticle systems, while the BNN was proposed to accurately predict the structural colors of gold nanoparticle systems and inversely design the geometric parameters for the desired colors. Taking the human chromatic discrimination ability as a criterion, our proposed approach achieved a high accuracy of 99.83% on the predicted colors and 98.5% on the designed geometric parameters. This work provides a general method to accurately and efficiently design the structural colors of nanoparticle systems, which can be exploited in a variety of applications and contribute to the development of advanced optical materials.

Topics & Concepts

Structural colorationArtificial neural networkHueMonte Carlo methodNanoparticleMaterials scienceBrightnessComputer scienceColloidal goldInverseBiological systemArtificial intelligenceOpticsNanotechnologyOptoelectronicsMathematicsPhysicsGeometryPhotonic crystalStatisticsBiologyPigment Synthesis and PropertiesColor Science and ApplicationsNonlinear Optical Materials Studies