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Active Learning Accelerates Design and Optimization of Hole-Transporting Materials for Organic Electronics

Hadi Abroshan, H. Shaun Kwak, Yuling An, Christopher T. Brown, Anand Chandrasekaran, Paul Winget, Mathew D. Halls

2022Frontiers in Chemistry24 citationsDOIOpen Access PDF

Abstract

Data-driven methods are receiving increasing attention to accelerate materials design and discovery for organic light-emitting diodes (OLEDs). Machine learning (ML) has enabled high-throughput screening of materials properties to suggest new candidates for organic electronics. However, building reliable predictive ML models requires creating and managing a high volume of data that adequately address the complexity of materials' chemical space. In this regard, active learning (AL) has emerged as a powerful strategy to efficiently navigate the search space by prioritizing the decision-making process for unexplored data. This approach allows a more systematic mechanism to identify promising candidates by minimizing the number of computations required to explore an extensive materials library with diverse variables and parameters. In this paper, we applied a workflow of AL that accounts for multiple optoelectronic parameters to identify materials candidates for hole-transport layers (HTL) in OLEDs. Results of this work pave the way for efficient screening of materials for organic electronics with superior efficiencies before laborious simulations, synthesis, and device fabrication.

Topics & Concepts

OLEDWorkflowElectronicsComputer scienceOrganic electronicsChemical spaceProcess (computing)ThroughputNanotechnologyMaterials scienceWirelessEngineeringTelecommunicationsDrug discoveryElectrical engineeringBioinformaticsDatabaseOperating systemVoltageLayer (electronics)BiologyTransistorMachine Learning in Materials ScienceOrganic Electronics and PhotovoltaicsOrganic Light-Emitting Diodes Research
Active Learning Accelerates Design and Optimization of Hole-Transporting Materials for Organic Electronics | Litcius