Crystal graph attention networks for the prediction of stable materials

Schmidt, Jonathan; Pettersson, Love; Verdozzi, Claudio; Botti, Silvana; Marques, Miguel A. L.

doi:10.1126/sciadv.abi7948

Cited by 68 publications

(87 citation statements)

References 79 publications

(150 reference statements)

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“…Our starting point was the dataset used in the machine learning study of ref. 21 . This included PBE calculations stemming from the Materials Project database 2 , AFLOW 1 , and our own calculations.…”

Section: Methodsmentioning

confidence: 99%

“…In a previous work 21 we combined data from the AFLOW database 1 , the Materials Project 2 and from our own group to create a rather complete convex hull of thermodynamic stability at the PBE level. The details of the selection of the dataset can be found in ref.…”

Section: Background and Summarymentioning

confidence: 99%

“…The details of the selection of the dataset can be found in ref. 21 . Specifically, we selected all materials that were calculated with the same functional, pseudopotential, as well as U -parameters used in the Materials Project.…”

Section: Background and Summarymentioning

confidence: 99%

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A dataset of 175k stable and metastable materials calculated with the PBEsol and SCAN functionals

et al. 2022

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In the past decade we have witnessed the appearance of large databases of calculated material properties. These are most often obtained with the Perdew-Burke-Ernzerhof (PBE) functional of density-functional theory, a well established and reliable technique that is by now the standard in materials science. However, there have been recent theoretical developments that allow for increased accuracy in the calculations. Here, we present a dataset of calculations for 175k crystalline materials obtained with two functionals: geometry optimizations are performed with PBE for solids (PBEsol) that yields consistently better geometries than the PBE functional, and energies are obtained from PBEsol and from SCAN single-point calculations at the PBEsol geometry. Our results provide an accurate overview of the landscape of stable (and nearly stable) materials, and as such can be used for reliable predictions of novel compounds. They can also be used for training machine learning models, or even for the comparison and benchmark of PBE, PBEsol, and SCAN.

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Section: Methodsmentioning

confidence: 99%

Section: Background and Summarymentioning

confidence: 99%

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A dataset of 175k stable and metastable materials calculated with the PBEsol and SCAN functionals

et al. 2022

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“…[38] The attention mechanism has been adapted in several ML architectures for materials property prediction with improved accuracy. [28,30,33,37,[39][40][41][42] We show that Finder can outperform some state-of-the-art stoichiometry-only models such as Roost and compete with crystal graph models such as MEGNet and CGCNN on diverse benchmark databases curated from the Materials Project (MP) repository. Compared to other models revisited in this work, our model displays faster convergence and achieves lower errors at all training set sizes explored.…”

Section: Introductionmentioning

confidence: 99%

Formula Graph Self‐Attention Network for Representation‐Domain Independent Materials Discovery

Ihalage

Hao

2022

Advanced Science

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The success of machine learning (ML) in materials property prediction depends heavily on how the materials are represented for learning. Two dominant families of material descriptors exist, one that encodes crystal structure in the representation and the other that only uses stoichiometric information with the hope of discovering new materials. Graph neural networks (GNNs) in particular have excelled in predicting material properties within chemical accuracy. However, current GNNs are limited to only one of the above two avenues owing to the little overlap between respective material representations. Here, a new concept of formula graph which unifies stoichiometry-only and structure-based material descriptors is introduced. A self-attention integrated GNN that assimilates a formula graph is further developed and it is found that the proposed architecture produces material embeddings transferable between the two domains. The proposed model can outperform some previously reported structure-agnostic models and their structure-based counterparts while exhibiting better sample efficiency and faster convergence. Finally, the model is applied in a challenging exemplar to predict the complex dielectric function of materials and nominate new substances that potentially exhibit epsilon-near-zero phenomena.

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“…We based our approach on the use of machine learning (ML) techniques, with a focus on probabilistic models and artificial neural networks. Limited by the amount of available composition-property data, conventional ML approaches in alloy design have to predominantly rely on simulation data, often with only limited experimental validation ( 9 , 10 ). As the experimental microstructure database continues to expand, ML obtains higher accuracy in predicting the phase or microstructure of materials ( 11 ).…”

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confidence: 99%

Machine learning–enabled high-entropy alloy discovery

Rao

Tung

Xie

et al. 2022

Science

220

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High-entropy alloys are solid solutions of multiple principal elements that are capable of reaching composition and property regimes inaccessible for dilute materials. Discovering those with valuable properties, however, too often relies on serendipity, because thermodynamic alloy design rules alone often fail in high-dimensional composition spaces. We propose an active learning strategy to accelerate the design of high-entropy Invar alloys in a practically infinite compositional space based on very sparse data. Our approach works as a closed-loop, integrating machine learning with density-functional theory, thermodynamic calculations, and experiments. After processing and characterizing 17 new alloys out of millions of possible compositions, we identified two high-entropy Invar alloys with extremely low thermal expansion coefficients around 2 × 10 −6 per degree kelvin at 300 kelvin. We believe this to be a suitable pathway for the fast and automated discovery of high-entropy alloys with optimal thermal, magnetic, and electrical properties.

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Crystal graph attention networks for the prediction of stable materials

Cited by 68 publications

References 79 publications

A dataset of 175k stable and metastable materials calculated with the PBEsol and SCAN functionals

A dataset of 175k stable and metastable materials calculated with the PBEsol and SCAN functionals

Formula Graph Self‐Attention Network for Representation‐Domain Independent Materials Discovery

Machine learning–enabled high-entropy alloy discovery

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