Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites

Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites

Combining high-throughput experiments with machine learning accelerates materials and process optimization toward user-specified target properties. In this study, a rapid machine learning-driven automated flow mixing setup with a high-throughput drop-casting system is introduced for thin film prepar...

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Main Authors: Bash, Daniil, Cai, Yongqiang, Chellappan, Vijila, Wong, Swee Liang, Xu, Yang, Kumar, Pawan, Tan, Jin Da, Abutaha, Anas, Cheng, Jayce J. W., Lim, Yee‐Fun, Tian, Siyu Isaac Parker, Ren, Zekun, Mekki‐Berrada, Flore, Wong, Wai Kuan, Xie, Jiaxun, Kumar, Jatin, Khan, Saif A., Li, Qianxiao, Buonassisi, Tonio, Hippalgaonkar, Kedar
Other Authors: School of Materials Science and Engineering
Format: Article
Language:English
Published: 2022
Subjects:
Engineering::Materials::Composite materials
Bayesian Optimization
Electrical Conductivity
Graphical Regression Models
High-Throughput Flow Mixing
Hypothesis Testing
Machine Learning
P3HT-CNT Composites
Online Access:https://hdl.handle.net/10356/156005
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1560052023-07-14T16:04:49Z Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites Bash, Daniil Cai, Yongqiang Chellappan, Vijila Wong, Swee Liang Xu, Yang Kumar, Pawan Tan, Jin Da Abutaha, Anas Cheng, Jayce J. W. Lim, Yee‐Fun Tian, Siyu Isaac Parker Ren, Zekun Mekki‐Berrada, Flore Wong, Wai Kuan Xie, Jiaxun Kumar, Jatin Khan, Saif A. Li, Qianxiao Buonassisi, Tonio Hippalgaonkar, Kedar School of Materials Science and Engineering Institute of Materials Research and Engineering, A*STAR Engineering::Materials::Composite materials Bayesian Optimization Electrical Conductivity Graphical Regression Models High-Throughput Flow Mixing Hypothesis Testing Machine Learning P3HT-CNT Composites Combining high-throughput experiments with machine learning accelerates materials and process optimization toward user-specified target properties. In this study, a rapid machine learning-driven automated flow mixing setup with a high-throughput drop-casting system is introduced for thin film preparation, followed by fast characterization of proxy optical and target electrical properties that completes one cycle of learning with 160 unique samples in a single day, a >10× improvement relative to quantified, manual-controlled baseline. Regio-regular poly-3-hexylthiophene is combined with various types of carbon nanotubes, to identify the optimum composition and synthesis conditions to realize electrical conductivities as high as state-of-the-art 1000 S cm−1. The results are subsequently verified and explained using offline high-fidelity experiments. Graph-based model selection strategies with classical regression that optimize among multi-fidelity noisy input-output measurements are introduced. These strategies present a robust machine-learning driven high-throughput experimental scheme that can be effectively applied to understand, optimize, and design new materials and composites. Agency for Science, Technology and Research (A*STAR) Submitted/Accepted version The authors acknowledge funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology and Research under Grant No. A1898b0043. 2022-03-30T05:32:22Z 2022-03-30T05:32:22Z 2021 Journal Article Bash, D., Cai, Y., Chellappan, V., Wong, S. L., Xu, Y., Kumar, P., Tan, J. D., Abutaha, A., Cheng, J. J. W., Lim, Y., Tian, S. I. P., Ren, Z., Mekki‐Berrada, F., Wong, W. K., Xie, J., Kumar, J., Khan, S. A., Li, Q., Buonassisi, T. & Hippalgaonkar, K. (2021). Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites. Advanced Functional Materials, 31(36), 2102606-. https://dx.doi.org/10.1002/adfm.202102606 1616-301X https://hdl.handle.net/10356/156005 10.1002/adfm.202102606 36 31 2102606 en A1898b0043 Advanced Functional Materials This is the peer reviewed version of the following article: Bash, D., Cai, Y., Chellappan, V., Wong, S. L., Xu, Y., Kumar, P., Tan, J. D., Abutaha, A., Cheng, J. J. W., Lim, Y., Tian, S. I. P., Ren, Z., Mekki‐Berrada, F., Wong, W. K., Xie, J., Kumar, J., Khan, S. A., Li, Q., Buonassisi, T. & Hippalgaonkar, K. (2021). Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites. Advanced Functional Materials, 31(36), 2102606, which has been published in final form at https://doi.org/10.1002/adfm.202102606. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. application/pdf application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Materials::Composite materials
Bayesian Optimization
Electrical Conductivity
Graphical Regression Models
High-Throughput Flow Mixing
Hypothesis Testing
Machine Learning
P3HT-CNT Composites
spellingShingle Engineering::Materials::Composite materials
Bayesian Optimization
Electrical Conductivity
Graphical Regression Models
High-Throughput Flow Mixing
Hypothesis Testing
Machine Learning
P3HT-CNT Composites
Bash, Daniil
Cai, Yongqiang
Chellappan, Vijila
Wong, Swee Liang
Xu, Yang
Kumar, Pawan
Tan, Jin Da
Abutaha, Anas
Cheng, Jayce J. W.
Lim, Yee‐Fun
Tian, Siyu Isaac Parker
Ren, Zekun
Mekki‐Berrada, Flore
Wong, Wai Kuan
Xie, Jiaxun
Kumar, Jatin
Khan, Saif A.
Li, Qianxiao
Buonassisi, Tonio
Hippalgaonkar, Kedar
Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
description Combining high-throughput experiments with machine learning accelerates materials and process optimization toward user-specified target properties. In this study, a rapid machine learning-driven automated flow mixing setup with a high-throughput drop-casting system is introduced for thin film preparation, followed by fast characterization of proxy optical and target electrical properties that completes one cycle of learning with 160 unique samples in a single day, a >10× improvement relative to quantified, manual-controlled baseline. Regio-regular poly-3-hexylthiophene is combined with various types of carbon nanotubes, to identify the optimum composition and synthesis conditions to realize electrical conductivities as high as state-of-the-art 1000 S cm−1. The results are subsequently verified and explained using offline high-fidelity experiments. Graph-based model selection strategies with classical regression that optimize among multi-fidelity noisy input-output measurements are introduced. These strategies present a robust machine-learning driven high-throughput experimental scheme that can be effectively applied to understand, optimize, and design new materials and composites.
author2 School of Materials Science and Engineering
author_facet School of Materials Science and Engineering
Bash, Daniil
Cai, Yongqiang
Chellappan, Vijila
Wong, Swee Liang
Xu, Yang
Kumar, Pawan
Tan, Jin Da
Abutaha, Anas
Cheng, Jayce J. W.
Lim, Yee‐Fun
Tian, Siyu Isaac Parker
Ren, Zekun
Mekki‐Berrada, Flore
Wong, Wai Kuan
Xie, Jiaxun
Kumar, Jatin
Khan, Saif A.
Li, Qianxiao
Buonassisi, Tonio
Hippalgaonkar, Kedar
format Article
author Bash, Daniil
Cai, Yongqiang
Chellappan, Vijila
Wong, Swee Liang
Xu, Yang
Kumar, Pawan
Tan, Jin Da
Abutaha, Anas
Cheng, Jayce J. W.
Lim, Yee‐Fun
Tian, Siyu Isaac Parker
Ren, Zekun
Mekki‐Berrada, Flore
Wong, Wai Kuan
Xie, Jiaxun
Kumar, Jatin
Khan, Saif A.
Li, Qianxiao
Buonassisi, Tonio
Hippalgaonkar, Kedar
author_sort Bash, Daniil
title Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
title_short Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
title_full Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
title_fullStr Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
title_full_unstemmed Multi-fidelity high-throughput optimization of electrical conductivity in P3HT-CNT composites
title_sort multi-fidelity high-throughput optimization of electrical conductivity in p3ht-cnt composites
publishDate 2022
url https://hdl.handle.net/10356/156005
_version_ 1773551420155363328

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