Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites

Daniil Bash; Yongqiang Cai; Vijila Chellappan; Swee Liang Wong; Xu Yang; Pawan Kumar; Jin Da Tan; Anas Abutaha; Jayce J.W. Cheng; Yee Fun Lim; Siyu Isaac Parker Tian; Zekun Ren; Flore Mekki-Berrada; Wai Kuan Wong; Jiaxun Xie; Jatin Kumar; Saif A. Khan; Qianxiao Li; Tonio Buonassisi; Kedar Hippalgaonkar

doi:10.1002/adfm.202102606

Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites

Daniil Bash
, Yongqiang Cai
, Vijila Chellappan
, Swee Liang Wong
, Xu Yang
, Pawan Kumar
, Jin Da Tan
, Anas Abutaha
, Jayce J.W. Cheng
, Yee Fun Lim
, Siyu Isaac Parker Tian
, Zekun Ren
, Flore Mekki-Berrada
, Wai Kuan Wong
, Jiaxun Xie
, Jatin Kumar
, Saif A. Khan
, Qianxiao Li^*
, Tonio Buonassisi^*
, Kedar Hippalgaonkar^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

39 Citations (Scopus)

Abstract

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.

Original language	English
Article number	2102606
Journal	Advanced Functional Materials
Volume	31
Issue number	36
DOIs	https://doi.org/10.1002/adfm.202102606
Publication status	Published - 2 Sept 2021
Externally published	Yes

Keywords

Bayesian optimization
electrical conductivity
graphical regression models
high-throughput flow mixing
hypothesis testing
machine learning
p3ht-cnt composites

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10.1002/adfm.202102606

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Bash, D., Cai, Y., Chellappan, V., Wong, S. L., Yang, X., Kumar, P., Tan, J. D., Abutaha, A., Cheng, J. J. W., Lim, Y. F., 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), Article 2102606. https://doi.org/10.1002/adfm.202102606

@article{7919588c938e4f0787205fefce7636c9,

title = "Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites",

abstract = "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.",

keywords = "Bayesian optimization, electrical conductivity, graphical regression models, high-throughput flow mixing, hypothesis testing, machine learning, p3ht-cnt composites",

author = "Daniil Bash and Yongqiang Cai and Vijila Chellappan and Wong, \{Swee Liang\} and Xu Yang and Pawan Kumar and Tan, \{Jin Da\} and Anas Abutaha and Cheng, \{Jayce J.W.\} and Lim, \{Yee Fun\} and Tian, \{Siyu Isaac Parker\} and Zekun Ren and Flore Mekki-Berrada and Wong, \{Wai Kuan\} and Jiaxun Xie and Jatin Kumar and Khan, \{Saif A.\} and Qianxiao Li and Tonio Buonassisi and Kedar Hippalgaonkar",

note = "Publisher Copyright: {\textcopyright} 2021 Wiley-VCH GmbH",

year = "2021",

month = sep,

day = "2",

doi = "10.1002/adfm.202102606",

language = "English",

volume = "31",

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Bash, D, Cai, Y, Chellappan, V, Wong, SL, Yang, X, Kumar, P, Tan, JD, Abutaha, A, Cheng, JJW, Lim, YF, Tian, SIP, Ren, Z, Mekki-Berrada, F, Wong, WK, Xie, J, Kumar, J, Khan, SA, Li, Q, Buonassisi, T & Hippalgaonkar, K 2021, 'Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites', Advanced Functional Materials, vol. 31, no. 36, 2102606. https://doi.org/10.1002/adfm.202102606

TY - JOUR

T1 - Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites

AU - Bash, Daniil

AU - Cai, Yongqiang

AU - Chellappan, Vijila

AU - Wong, Swee Liang

AU - Yang, Xu

AU - Kumar, Pawan

AU - Tan, Jin Da

AU - Abutaha, Anas

AU - Cheng, Jayce J.W.

AU - Lim, Yee Fun

AU - Tian, Siyu Isaac Parker

AU - Ren, Zekun

AU - Mekki-Berrada, Flore

AU - Wong, Wai Kuan

AU - Xie, Jiaxun

AU - Kumar, Jatin

AU - Khan, Saif A.

AU - Li, Qianxiao

AU - Buonassisi, Tonio

AU - Hippalgaonkar, Kedar

PY - 2021/9/2

Y1 - 2021/9/2

N2 - 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.

AB - 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.

KW - Bayesian optimization

KW - electrical conductivity

KW - graphical regression models

KW - high-throughput flow mixing

KW - hypothesis testing

KW - machine learning

KW - p3ht-cnt composites

UR - https://www.scopus.com/pages/publications/85108799344

U2 - 10.1002/adfm.202102606

DO - 10.1002/adfm.202102606

M3 - Article

AN - SCOPUS:85108799344

SN - 1616-301X

VL - 31

JO - Advanced Functional Materials

JF - Advanced Functional Materials

IS - 36

M1 - 2102606

ER -

Multi-Fidelity High-Throughput Optimization of Electrical Conductivity in P3HT-CNT Composites

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Keywords

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