Deep learning for the modeling and inverse design of radiative heat transfer

García-Esteban, Juan José; Bravo-Abad, Jorge; Cuevas, Juan Carlos

doi:10.48550/arxiv.2109.03114

Cited by 2 publications

(1 citation statement)

References 83 publications

(122 reference statements)

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“…In another application, Liu et al [40] implemented an ensemble of convolutional neural networks (CNNs) to generate optimal surface patterns for structured metasurfaces, where the input to the network was a desired spectral transmittance distribution. Lastly, Garcia et al [41] demonstrated how deep learning techniques can be implemented for the modeling and inverse design of radiative heat transfer phenomena in various systems including hyperbolic metamaterials, passive radiative cooling in photonic-crystals, and emissive power of subwavelength objects.…”

Section: Introductionmentioning

confidence: 99%

Emissivity Prediction of Functionalized Surfaces Using Artificial Intelligence

Acosta,

Reicks,

Moreno

et al. 2022

Preprint

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The radiative response of any object is governed by a surface parameter known as emissivity. Tuning the emissivity of surfaces has been of great interest in many applications involving thermal radiation such as thermophotovoltaics, thermal management systems, and passive radiative cooling. Although several surface engineering techniques (e.g., surface functionalization) have been pursued to alter the emissivity, there exists a knowledge gap in precisely predicting the emissivity of a surface prior to the modification/fabrication process. Predicting emissivity by a physics-based modeling approach is challenging due to surface's contributing factors, complex interactions and interdependence, and measuring the emissivity requires a tedious procedure for every sample. Thus, a new approach is much-needed to systematically predict the emissivity and expand the applications of thermal radiation. In this work, we demonstrate the immense advantage of employing artificial intelligence (AI) techniques to predict the emissivity of complex surfaces. For this aim, we fabricated 116 bulk aluminum 6061 samples with various surface characteristics using femtosecond laser surface processing (FLSP). A comprehensive dataset was established by collecting surface characteristic data, laser operating parameters, and measured emissivities for all samples. We demonstrated the application of AI in two distinct scenarios. First, the range of emissivity of an unknown sample was shown to be estimated correctly solely based on its 3D surface morphology image. Second,

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Section: Introductionmentioning

confidence: 99%

Emissivity Prediction of Functionalized Surfaces Using Artificial Intelligence

Acosta,

Reicks,

Moreno

et al. 2022

Preprint

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Designing thermal radiation metamaterials via a hybrid adversarial autoencoder and Bayesian optimization

Zhu

Guo

et al. 2022

Opt. Lett.

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Designing thermal radiation metamaterials is challenging especially for problems with high degrees of freedom and complex objectives. In this Letter, we develop a hybrid materials informatics approach which combines the adversarial autoencoder and Bayesian optimization to design narrowband thermal emitters at different target wavelengths. With only several hundreds of training data sets, new structures with optimal properties can be quickly determined in a compressed two-dimensional latent space. This enables the optimal design by calculating far less than 0.001% of the total candidate structures, which greatly decreases the design period and cost. The proposed design framework can be easily extended to other thermal radiation metamaterials design with higher dimensional features.

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Deep learning for the modeling and inverse design of radiative heat transfer

Cited by 2 publications

References 83 publications

Emissivity Prediction of Functionalized Surfaces Using Artificial Intelligence

Emissivity Prediction of Functionalized Surfaces Using Artificial Intelligence

Designing thermal radiation metamaterials via a hybrid adversarial autoencoder and Bayesian optimization

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