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

Abroshan, Hadi; Kwak, Hyunwook; An, Yuling; Brown, Christopher T.; Chandrasekaran, Anand; Winget, Paul

doi:10.3389/fchem.2021.800371

Cited by 17 publications

(24 citation statements)

References 29 publications

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“…[ 130 ] ML can also be used to propose structures with a given set of properties, addressing the inverse design problem. [ 131 ] This process can be further optimized by using active machine learning [ 132 , 133 ] or generative models. [ 134 ]…”

Section: Discussionmentioning

confidence: 99%

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

et al. 2022

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We dedicate this contribution to Klaus Müllen on the occasion of his 75th birthday. He advanced the synthesis and application of organic electronic compounds in an internationally leading position for many years and always challenged theory to provide a better understanding.The field of organic semiconductors is multifaceted and the potentially suitable molecular compounds are very diverse. Representative examples include discotic liquid crystals, dye-sensitized solar cells, conjugated polymers, and graphene-based low-dimensional materials. This huge variety not only represents enormous challenges for synthesis but also for theory, which aims at a comprehensive understanding and structuring of the plethora of possible compounds. Eventually computational methods should point to new, better materials, which have not yet been synthesized. In this perspective, it is shown that the answer to this question rests upon the delicate balance between computational efficiency and accuracy of the methods used in the virtual screening. To illustrate the fundamentals of virtual screening, chemical design of non-fullerene acceptors, thermally activated delayed fluorescence emitters, and nanographenes are discussed.

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Section: Discussionmentioning

confidence: 99%

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

et al. 2022

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“…Active learning (AL) has emerged as a promising strategy to address this issue. 2 By prioritizing the decision-making process with unexplored new data, allowing an efficient exploration of an extensive library, see Figure 1. A feedback loop in the AL framework enables an efficient data selection, leading to a smaller training set required for ML.…”

Section: Introductionmentioning

confidence: 99%

“…Despite the successful application of AL in different fields of application, such as lithium-ion batteries, catalysis, and drug discovery, the design and development of novel optoelectronic materials via data-driven approaches are in their early stages. 2 There are several complex factors that simultaneously impact the efficiency of materials in optoelectronic devices. As a direct consequence, reliable application of ML models for the design and development of optoelectronic materials by using simplistic descriptors such as energy levels of frontier molecular orbitals is generally impractical.…”

Section: Introductionmentioning

confidence: 99%

66‐3: Active Learning for the Design of Novel OLED Materials

Abroshan

Chandrasekaran

Winget

et al. 2022

Symp Digest of Tech Papers

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This work demonstrates an active learning (AL) workflow for identifying promising material candidates for organic lightemitting diodes (OLEDs) based on multiple optoelectronic parameters while minimizing the number of physics‐based computations to explore an extensive library. This work paves the way for efficient computational materials screening before laborious synthesis, and device fabrication.

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“…This strategy is called active learning or sequential learning. Recently active learning has received much attention in a wide range of applications such as alloys, thermoelectrics, batteries, , OLEDs, and OSCs other organic semiconducting materials …”

Section: Introductionmentioning

confidence: 99%

“…Therefore, active learning is most beneficial in situations when data are few or challenging to gather, which is frequently the case in materials research. In fact, recent literature from a variety of areas has highlighted successful examples of active learning in discovery of new materials. ,, An important thing to note is that the buzzword “big data” refers to the search space, while the data set available for training is usually small and sparse, like in all other scientific domains. Thus, extrapolation is required, and traditional ML techniques might struggle to achieve it.…”

Section: Introductionmentioning

confidence: 99%

Active Discovery of Donor:Acceptor Combinations For Efficient Organic Solar Cells

Malhotra

Verduzco²,

Biswas

et al. 2022

ACS Appl. Mater. Interfaces

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The structural flexibility of organic semiconductors offers vast a search space, and many potential candidates (donor and acceptor) for organic solar cells (OSCs) are yet to be discovered. Machine learning is extensively used for material discovery but performs poorly on extrapolation tasks with small training data sets. Active learning techniques can guide experimentalists to extrapolate and find the most promising D:A combination in a significantly small number of experiments. This study uses an active learning technique with a predictive random forest model to iteratively find the most optimal D:A combinations in the search space using various acquisition functions. Active learning results with five different acquisition functions (MM, MEI, MLI, MU, and UCB) are compared. Results reveal that acquisition functions that combine exploitation and exploration (MEI, MLI, and UCB) perform far better than purely exploiting (MM) and purely exploring (MU) acquisition functions. Interestingly, the proposed model can overcome the bottleneck of extrapolating small training data sets and find most promising D:A combinations in relatively fewer experiments.

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

Cited by 17 publications

References 29 publications

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

66‐3: Active Learning for the Design of Novel OLED Materials

Active Discovery of Donor:Acceptor Combinations For Efficient Organic Solar Cells

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