A strategy to apply machine learning to small datasets in materials science

Zhang, Ying; Ling, Chen

doi:10.1038/s41524-018-0081-z

Cited by 530 publications

(403 citation statements)

References 63 publications

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“…For example, using the mean and standard deviation of elemental descriptors and BOP, the best model developed on 110 compounds for log-scaled κ l gives RMSE of 0.096 [6]. In another model developed on 93 compounds, the difference between experimental and predicted values of κ l has been reported to lie within a factor of 1.5-2 [52]. Using the descriptors related directly to the physics of κ l , a prediction model developed on 120 compounds gives RMSE of 0.21 [22].…”

Section: Resultsmentioning

confidence: 99%

Guided patchwork kriging to develop highly transferable thermal conductivity prediction models

Juneja

Singh

2020

J. Phys. Mater.

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The machine learning models developed on a dataset comprising particular class of materials show poor transferability across different classes. The problem can be partially solved by increasing the variability in the dataset at the cost of prediction accuracy. To develop a model on a highly variable database, we propose a localized regression based patchwork kriging approach for capturing most of the complex details in the data. In this approach, the data is partitioned into smaller regions with shared patches of few datapoints across the neighboring boundaries. Local regression functions are developed in each partition with a constrain to give similar performance at the boundary. Out of 17 different properties tried for partitioning the data, the decomposition with respect to target output κ l gave local models with unprecedented accuracies. The partitioning with respect to κ l , however, requires its estimate for any unknown compound beforehand. To address this, we developed a global model for the entire database. The global model accurately predicts the order of magnitude of κ l for the compounds in the dataset and hence, directs them towards a particular partition for more accurate prediction. We define this stepwise approach as guided patchwork kriging, which can be applied to develop highly accurate transferable prediction models.

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Section: Resultsmentioning

confidence: 99%

Guided patchwork kriging to develop highly transferable thermal conductivity prediction models

Juneja

Singh

2020

J. Phys. Mater.

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“…When both α 1 and α 2 are nonzero, the elastic net model is obtained. The ridge and LASSO regression models have found wide applications in materials ML to solve the small‐data problem, compute phonons using compressive sensing, perform feature selection, and avoid overfitting …”

Section: Model Selection and Trainingmentioning

confidence: 99%

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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“…18,21 In the absence of an analytic model or high-throughput defect calculations, statistical learning from experimental or computational data can serve as an alternative to create empirical models and rules of thumb to make predictions of dopability in new compounds. Machine learning has proven successful in understanding and predicting energy and entropy, 29 potentials and forces, [30][31][32] structure, physical, and elastic properties, [33][34][35][36][37][38] bandgap, 34,39,40 and defects, 41 as well as enabling high-throughput screening and discovery, [42][43][44][45][46] and guiding experimental synthesis. 47,48 In order to properly model and interpret dopability, the construction of an empirical dataset for cross-validation is of vital importance.…”

Section: Introductionmentioning

confidence: 99%

Empirical modeling of dopability in diamond-like semiconductors

et al. 2018

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Carrier concentration optimization has been an enduring challenge when developing newly discovered semiconductors for applications (e.g., thermoelectrics, transparent conductors, photovoltaics). This barrier has been particularly pernicious in the realm of high-throughput property prediction, where the carrier concentration is often assumed to be a free parameter and the limits are not predicted due to the high computational cost. In this work, we explore the application of machine learning for high-throughput carrier concentration range prediction. Bounding the model within diamond-like semiconductors, the learning set was developed from experimental carrier concentration data on 127 compounds ranging from unary to quaternary. The data were analyzed using various statistical and machine learning methods. Accurate predictions of carrier concentration ranges in diamond-like semiconductors are made within approximately one order of magnitude on average across both p-and n-type dopability. The model fit to empirical data is analyzed to understand what drives trends in carrier concentration and compared with previous computational efforts. Finally, dopability predictions from this model are combined with high-throughput quality factor predictions to identify promising thermoelectric materials.

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A strategy to apply machine learning to small datasets in materials science

Cited by 530 publications

References 63 publications

Guided patchwork kriging to develop highly transferable thermal conductivity prediction models

Guided patchwork kriging to develop highly transferable thermal conductivity prediction models

A Critical Review of Machine Learning of Energy Materials

Empirical modeling of dopability in diamond-like semiconductors

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