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Machine learning and high-throughput robust design of P3HT-CNT composite thin films for high electrical conductivity

Authors :
Bash, Daniil
Cai, Yongqiang
Chellappan, Vijila
Wong, Swee Liang
Xu, Yang
Kumar, Pawan
Da Tan, Jin
Abutaha, Anas
Cheng, Jayce
Lim, Yee Fun
Tian, Siyu
Ren, Danny Zekun
Mekki-Barrada, Flore
Wong, Wai Kuan
Kumar, Jatin
Khan, Saif
Li, Qianxiao
Buonassisi, Tonio
Hippalgaonkar, Kedar
Publication Year :
2020

Abstract

Combining high-throughput experiments with machine learning allows quick optimization of parameter spaces towards achieving target properties. In this study, we demonstrate that machine learning, combined with multi-labeled datasets, can additionally be used for scientific understanding and hypothesis testing. We introduce an automated flow system with high-throughput drop-casting for thin film preparation, followed by fast characterization of optical and electrical properties, with the capability to complete one cycle of learning of fully labeled ~160 samples in a single day. We combine regio-regular poly-3-hexylthiophene with various carbon nanotubes to achieve electrical conductivities as high as 1200 S/cm. Interestingly, a non-intuitive local optimum emerges when 10% of double-walled carbon nanotubes are added with long single wall carbon nanotubes, where the conductivity is seen to be as high as 700 S/cm, which we subsequently explain with high fidelity optical characterization. Employing dataset resampling strategies and graph-based regressions allows us to account for experimental cost and uncertainty estimation of correlated multi-outputs, and supports the proving of the hypothesis linking charge delocalization to electrical conductivity. We therefore present a robust machine-learning driven high-throughput experimental scheme that can be applied to optimize and understand properties of composites, or hybrid organic-inorganic materials.<br />Comment: 10 pages, 5 figures, includes Supplementary Information

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.2011.10382
Document Type :
Working Paper