Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report

Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report

Abstract Using reinforcement learning, a deep Q-network was used to design polarization-independent, perfect solar absorbers. The deep Q-network selected the geometrical properties and materials of a symmetric three-layer metamaterial made up of circular rods on top of two films. The combination of...

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Main Authors: Iman Sajedian, Trevon Badloe, Heon Lee, Junsuk Rho
Format: Article
Language:English
Published: SpringerOpen 2020-08-01
Series:Nano Convergence
Subjects:
Reinforcement learning
Deep Q-learning
Perfect solar absorbers
Statistical analysis
Online Access:http://link.springer.com/article/10.1186/s40580-020-00233-8
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spelling doaj-7afe921b46354a52b890554b242747b02020-11-25T03:34:24ZengSpringerOpenNano Convergence2196-54042020-08-01711710.1186/s40580-020-00233-8Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical reportIman Sajedian0Trevon Badloe1Heon Lee2Junsuk Rho3Department of Materials Science and Engineering, Korea UniversityDepartment of Mechanical Engineering, Pohang University of Science and Technology (POSTECH)Department of Materials Science and Engineering, Korea UniversityDepartment of Mechanical Engineering, Pohang University of Science and Technology (POSTECH)Abstract Using reinforcement learning, a deep Q-network was used to design polarization-independent, perfect solar absorbers. The deep Q-network selected the geometrical properties and materials of a symmetric three-layer metamaterial made up of circular rods on top of two films. The combination of all the possible permutations gives around 500 billion possible designs. In around 30,000 steps, the deep Q-network was able to produce 1250 structures that have an integrated absorption of higher than 90% in the visible region, with a maximum of 97.6% and an integrated absorption of less than 10% in the 8–13 µm wavelength region, with a minimum of 1.37%. A statistical analysis of the distribution of materials and geometrical parameters that make up the solar absorbers is presented.http://link.springer.com/article/10.1186/s40580-020-00233-8Reinforcement learningDeep Q-learningPerfect solar absorbersStatistical analysis
collection DOAJ
language English
format Article
sources DOAJ
author Iman Sajedian
Trevon Badloe
Heon Lee
Junsuk Rho
spellingShingle Iman Sajedian
Trevon Badloe
Heon Lee
Junsuk Rho
Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
Nano Convergence
Reinforcement learning
Deep Q-learning
Perfect solar absorbers
Statistical analysis
author_facet Iman Sajedian
Trevon Badloe
Heon Lee
Junsuk Rho
author_sort Iman Sajedian
title Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
title_short Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
title_full Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
title_fullStr Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
title_full_unstemmed Deep Q-network to produce polarization-independent perfect solar absorbers: a statistical report
title_sort deep q-network to produce polarization-independent perfect solar absorbers: a statistical report
publisher SpringerOpen
series Nano Convergence
issn 2196-5404
publishDate 2020-08-01
description Abstract Using reinforcement learning, a deep Q-network was used to design polarization-independent, perfect solar absorbers. The deep Q-network selected the geometrical properties and materials of a symmetric three-layer metamaterial made up of circular rods on top of two films. The combination of all the possible permutations gives around 500 billion possible designs. In around 30,000 steps, the deep Q-network was able to produce 1250 structures that have an integrated absorption of higher than 90% in the visible region, with a maximum of 97.6% and an integrated absorption of less than 10% in the 8–13 µm wavelength region, with a minimum of 1.37%. A statistical analysis of the distribution of materials and geometrical parameters that make up the solar absorbers is presented.
topic Reinforcement learning
Deep Q-learning
Perfect solar absorbers
Statistical analysis
url http://link.springer.com/article/10.1186/s40580-020-00233-8
work_keys_str_mv AT imansajedian deepqnetworktoproducepolarizationindependentperfectsolarabsorbersastatisticalreport
AT trevonbadloe deepqnetworktoproducepolarizationindependentperfectsolarabsorbersastatisticalreport
AT heonlee deepqnetworktoproducepolarizationindependentperfectsolarabsorbersastatisticalreport
AT junsukrho deepqnetworktoproducepolarizationindependentperfectsolarabsorbersastatisticalreport
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