Accelerated Discovery of Efficient Solar Cell Materials Using Quantum and Machine-Learning Methods

Choudhary, Kamal; Bercx, Marnik; Jiang, Jie; Pachter, Ruth; Lamoen, D.; Tavazza, Francesca

doi:10.1021/acs.chemmater.9b02166

Cited by 106 publications

(101 citation statements)

References 48 publications

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“…Using 256 GW calculations, the authors were able to identify in this group high‐SLME materials including almost all contemporary PV absorber materials. Choudhary et al have performed meta‐GGA calculations of bandgaps using the Tran–Blaha‐modified Becke–Johnson (TBmBJ) potential for 12 881 out of ≈30 000 materials in the JAVIS‐DFT database . The SLME metric was calculated on 5097 nonmetallic materials and the elemental distribution for high‐SLME materials is shown in Figure 8 a.…”

Section: Applicationmentioning

confidence: 99%

“…The SLMEs with direct bandgap values are shown in Figure 8b, where a consistent volcano shape as original SLME results using GW is obtained. A threshold of 10% was chosen to label high‐SMLE materials versus low‐SMLE materials, and the binarized data formed the training data set for ML modeling . The authors then used CFID as structure features and compared various classification models in terms of the classification AUC.…”

Section: Applicationmentioning

confidence: 99%

“…a) Element distribution for high‐SLME materials, b) the SLME distribution with direct bandgap values, and c) ROC curves for a GBDT model. Adapted with permission . Copyright 2019 American Chemical Society.…”

Section: Applicationmentioning

confidence: 99%

“…[7,66,115,116] The goal of such ML models is typically to bypass expensive and time-consuming experiments or firstprinciples computations. They have been used to provide guidance to experimental design, i.e., the next areas to explore for a potential "blockbuster" material for an application [117][118][119][120][121] as well as rapid computational screening of chemical spaces. [30,[122][123][124][125] ML-IAPs are also a subcategory of supervised materials ML models where the target is to predict the energies, forces and stresses, i.e., the potential energy surface, for a given atomic configuration.…”

Section: Model Categoriesmentioning

confidence: 99%

“…A threshold of 10% was chosen to label high-SMLE materials versus low-SMLE materials, and the binarized data formed the training data set for ML modeling. [120] The authors then used CFID as structure features and compared various classification models in terms of the classification AUC. The AUC for decision tree models, RF, kNN, MLP, and gradient boosting decision trees (GBDT) are 0.67, 0.79, 0.77, 0.80, and 0.87, respectively.…”

Section: Wwwadvancedsciencenewscommentioning

confidence: 99%

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A Critical Review of Machine Learning of Energy Materials

Chen

Zuo

et al. 2020

Advanced Energy Materials

399

281

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Machine learning (ML) is rapidly revolutionizing many fields and is starting to change landscapes for physics and chemistry. With its ability to solve complex tasks autonomously, ML is being exploited as a radically new way to help find material correlations, understand materials chemistry, and accelerate the discovery of materials. Here, an in‐depth review of the application of ML to energy materials, including rechargeable alkali‐ion batteries, photovoltaics, catalysts, thermoelectrics, piezoelectrics, and superconductors, is presented. A conceptual framework is first provided for ML in materials science, with a broad overview of different ML techniques as well as best practices. This is followed by a critical discussion of how ML is applied in energy materials. This review is concluded with the perspectives on major challenges and opportunities in this exciting field.

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Section: Applicationmentioning

confidence: 99%

Section: Applicationmentioning

confidence: 99%

Section: Applicationmentioning

confidence: 99%

Section: Model Categoriesmentioning

confidence: 99%

Section: Wwwadvancedsciencenewscommentioning

confidence: 99%

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A Critical Review of Machine Learning of Energy Materials

Chen

Zuo

et al. 2020

Advanced Energy Materials

399

281

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Artificial Intelligence in Material Engineering: A Review on Applications of Artificial Intelligence in Material Engineering

2023

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The role of artificial intelligence (AI) in material science and engineering (MSE) is becoming increasingly important as AI technology advances. The development of high‐performance computing has made it possible to test deep learning (DL) models with significant parameters, providing an opportunity to overcome the limitation of traditional computational methods, such as density functional theory (DFT), in property prediction. Machine learning (ML)‐based methods are faster and more accurate than DFT‐based methods. Furthermore, the generative adversarial networks (GANs) have facilitated the generation of chemical compositions of inorganic materials without using crystal structure information. These developments have significantly impacted material engineering (ME) and research. Some of the latest developments in AI in ME herein are reviewed. First, the development of AI in the critical areas of ME, such as in material processing, the study of structure and material property, and measuring the performance of materials in various aspects, is discussed. Then, the significant methods of AI and their uses in MSE, such as graph neural network, generative models, transfer of learning, etc. are discussed. The use of AI to analyze the results from existing analytical instruments is also discussed. Finally, AI's advantages, disadvantages, and future in ME are discussed.

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Identifying the Quantitative Relationship Between the Molecular Structure and the Horizontal Transition Dipole Orientation of TADF Emitters

Shi,

Zhang

et al. 2023

Advanced Optical Materials

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Realizing the horizontal orientation of molecular transition dipole moment (TDM) can greatly improve the out‐coupling efficiency and the resultant external quantum efficiency (EQE) of organic light‐emitting diodes (OLEDs). Herein, key parameters governing the horizontal TDM have been continuously explored. However, quantitatively identifying the key parameters from the molecular structure viewpoint is rather challenging due to the complexity of the influencing parameters. Here, by training the machine learning (ML) models using the experimental results, the quantitative relationship between the molecular structure and the horizontal TDM ratio (ϴ) of thermally activated delayed fluorescent (TADF) emitters in the host‐guest films is identified. The molecular structure is represented by either quantum chemistry‐calculated structural descriptors or topological/physical/chemical molecular descriptors. Key descriptors are ranked and can be used for guiding molecular structure design. Moreover, the accuracy of ML models is double‐verified by comparing the predicted results with experimental ϴ values and the trend of experimental EQE based on a group of materials. Using compressed sensing technology, the low‐dimension material space is also visually constructed based on key descriptors, and the results are consistent with those of the ML models.

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Accelerated Discovery of Efficient Solar Cell Materials Using Quantum and Machine-Learning Methods

Cited by 106 publications

References 48 publications

A Critical Review of Machine Learning of Energy Materials

A Critical Review of Machine Learning of Energy Materials

Artificial Intelligence in Material Engineering: A Review on Applications of Artificial Intelligence in Material Engineering

Identifying the Quantitative Relationship Between the Molecular Structure and the Horizontal Transition Dipole Orientation of TADF Emitters

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