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1. Atomic-scale probing of short-range order and its impact on electrochemical properties in cation-disordered oxide cathodes

Author

Linze Li, Bin Ouyang, Zhengyan Lun, Haoyan Huo, Dongchang Chen, Yuan Yue, Colin Ophus, Wei Tong, Guoying Chen, Gerbrand Ceder, and Chongmin Wang

Subjects
Science
Abstract

Abstract Chemical short-range-order has been widely noticed to dictate the electrochemical properties of Li-excess cation-disordered rocksalt oxides, a class of cathode based on earth abundant elements for next-generation high-energy-density batteries. Existence of short-range-order is normally evidenced by a diffused intensity pattern in reciprocal space, however, derivation of local atomic arrangements of short-range-order in real space is hardly possible. Here, by a combination of aberration-corrected scanning transmission electron microscopy, electron diffraction, and cluster-expansion Monte Carlo simulations, we reveal the short-range-order is a convolution of three basic types: tetrahedron, octahedron, and cube. We discover that short-range-order directly correlates with Li percolation channels, which correspondingly affects Li transport behavior. We further demonstrate that short-range-order can be effectively manipulated by anion doping or post-synthesis thermal treatment, creating new avenues for tailoring the electrochemical properties. Our results provide fundamental insights for decoding the complex relationship between local chemical ordering and properties of crystalline compounds.

Published
2023
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4. COVIDScholar: An automated COVID-19 research aggregation and analysis platform

Author

John Dagdelen, Amalie Trewartha, Haoyan Huo, Yuxing Fei, Tanjin He, Kevin Cruse, Zheren Wang, Akshay Subramanian, Benjamin Justus, Gerbrand Ceder, and Kristin A. Persson

Subjects
Medicine, Science
Abstract

The ongoing COVID-19 pandemic produced far-reaching effects throughout society, and science is no exception. The scale, speed, and breadth of the scientific community’s COVID-19 response lead to the emergence of new research at the remarkable rate of more than 250 papers published per day. This posed a challenge for the scientific community as traditional methods of engagement with the literature were strained by the volume of new research being produced. Meanwhile, the urgency of response lead to an increasingly prominent role for preprint servers and a diffusion of relevant research through many channels simultaneously. These factors created a need for new tools to change the way scientific literature is organized and found by researchers. With this challenge in mind, we present an overview of COVIDScholar https://covidscholar.org, an automated knowledge portal which utilizes natural language processing (NLP) that was built to meet these urgent needs. The search interface for this corpus of more than 260,000 research articles, patents, and clinical trials served more than 33,000 users at an average of 2,000 monthly active users and a peak of more than 8,600 weekly active users in the summer of 2020. Additionally, we include an analysis of trends in COVID-19 research over the course of the pandemic with a particular focus on the first 10 months, which represents a unique period of rapid worldwide shift in scientific attention.

Published
2023

5. Synthetic accessibility and stability rules of NASICONs

Author

Bin Ouyang, Jingyang Wang, Tanjin He, Christopher J. Bartel, Haoyan Huo, Yan Wang, Valentina Lacivita, Haegyeom Kim, and Gerbrand Ceder

Subjects
Science
Abstract

Sodium super ionic conductors are a class of promising energy storage materials owing to their high ionic conductivity. Here, the authors conducted high throughput calculations to understand the synthetic accessibility of NASICON-type materials and demonstrate an efficient paradigm for discovering new complex materials.

Published
2021
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6. Opportunities and challenges of text mining in materials research

Author

Olga Kononova, Tanjin He, Haoyan Huo, Amalie Trewartha, Elsa A. Olivetti, and Gerbrand Ceder

Subjects
Data Analysis, Computing Methodology, Computational Materials Science, Materials Design, Science
Abstract

Summary: Research publications are the major repository of scientific knowledge. However, their unstructured and highly heterogenous format creates a significant obstacle to large-scale analysis of the information contained within. Recent progress in natural language processing (NLP) has provided a variety of tools for high-quality information extraction from unstructured text. These tools are primarily trained on non-technical text and struggle to produce accurate results when applied to scientific text, involving specific technical terminology. During the last years, significant efforts in information retrieval have been made for biomedical and biochemical publications. For materials science, text mining (TM) methodology is still at the dawn of its development. In this review, we survey the recent progress in creating and applying TM and NLP approaches to materials science field. This review is directed at the broad class of researchers aiming to learn the fundamentals of TM as applied to the materials science publications.

Published
2021
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13. Toward autonomous design and synthesis of novel inorganic materials

Author

Haegyeom Kim, Yan Zeng, Christopher J. Bartel, N.J. Szymanski, Haoyan Huo, and Gerbrand Ceder

Subjects
Computer science, business.industry, Active learning (machine learning), Process Chemistry and Technology, Deep learning, Context (language use), Robotics, Chemistry Techniques, Synthetic, Automation, Characterization (materials science), Identification (information), Artificial Intelligence, Mechanics of Materials, Systems engineering, General Materials Science, Artificial intelligence, Electrical and Electronic Engineering, business, Algorithms, Inorganic Syntheses
Abstract

Autonomous experimentation driven by artificial intelligence (AI) provides an exciting opportunity to revolutionize inorganic materials discovery and development. Herein, we review recent progress in the design of self-driving laboratories, including robotics to automate materials synthesis and characterization, in conjunction with AI to interpret experimental outcomes and propose new experimental procedures. We focus on efforts to automate inorganic synthesis through solution-based routes, solid-state reactions, and thin film deposition. In each case, connections are made to relevant work in organic chemistry, where automation is more common. Characterization techniques are primarily discussed in the context of phase identification, as this task is critical to understand what products have formed during synthesis. The application of deep learning to analyze multivariate characterization data and perform phase identification is examined. To achieve "closed-loop" materials synthesis and design, we further provide a detailed overview of optimization algorithms that use active learning to rationally guide experimental iterations. Finally, we highlight several key opportunities and challenges for the future development of self-driving inorganic materials synthesis platforms.

Published
2021
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14. Machine-learning rationalization and prediction of solid-state synthesis conditions

Author

Haoyan Huo, Christopher J. Bartel, Tanjin He, Amalie Trewartha, Alexander Dunn, Bin Ouyang, Anubhav Jain, and Gerbrand Ceder

Subjects
Condensed Matter - Materials Science, Engineering, General Chemical Engineering, Chemical Sciences, Materials Chemistry, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, General Chemistry, Materials
Abstract

There currently exist no quantitative methods to determine the appropriate conditions for solid-state synthesis. This not only hinders the experimental realization of novel materials but also complicates the interpretation and understanding of solid-state reaction mechanisms. Here, we demonstrate a machine-learning approach that predicts synthesis conditions using large solid-state synthesis datasets text-mined from scientific journal articles. Using feature importance ranking analysis, we discovered that optimal heating temperatures have strong correlations with the stability of precursor materials quantified using melting points and formation energies ($\Delta G_f$, $\Delta H_f$). In contrast, features derived from the thermodynamics of synthesis-related reactions did not directly correlate to the chosen heating temperatures. This correlation between optimal solid-state heating temperature and precursor stability extends Tamman's rule from intermetallics to oxide systems, suggesting the importance of reaction kinetics in determining synthesis conditions. Heating times are shown to be strongly correlated with the chosen experimental procedures and instrument setups, which may be indicative of human bias in the dataset. Using these predictive features, we constructed machine-learning models with good performance and general applicability to predict the conditions required to synthesize diverse chemical systems. Codes and data used in this work can be found at: https://github.com/CederGroupHub/s4.

Published
2022

15. Quantifying the advantage of domain-specific pre-training on named entity recognition tasks in materials science

Author

Amalie Trewartha, Nicholas Walker, Haoyan Huo, Sanghoon Lee, Kevin Cruse, John Dagdelen, Alexander Dunn, Kristin A. Persson, Gerbrand Ceder, and Anubhav Jain

Subjects
07.00.00 [gold nanoparticles PACS], materials science, pre-train, NER, language model, transformer, General Decision Sciences, doping, 81.00.00, NLP, solid-state, BERT
Abstract

A bottleneck in efficiently connecting new materials discoveries to established literature has arisen due to an increase in publications. This problem may be addressed by using named entity recognition (NER) to extract structured summary-level data from unstructured materials science text. We compare the performance of four NER models on three materials science datasets. The four models include a bidirectional long short-term memory (BiLSTM) and three transformer models (BERT, SciBERT, and MatBERT) with increasing degrees of domain-specific materials science pre-training. MatBERT improves over the other two BERTBASE-based models by 1%∼12%, implying that domain-specific pre-training provides measurable advantages. Despite relative architectural simplicity, the BiLSTM model consistently outperforms BERT, perhaps due to its domain-specific pre-trained word embeddings. Furthermore, MatBERT and SciBERT models outperform the original BERT model to a greater extent in the small data limit. MatBERT's higher-quality predictions should accelerate the extraction of structured data from materials science literature.

Published
2021

16. Synthetic accessibility and stability rules of NASICONs

Author

Tanjin He, Haoyan Huo, Jingyang Wang, Gerbrand Ceder, Bin Ouyang, Haegyeom Kim, Yan Wang, Christopher J. Bartel, and Valentina Lacivita

Subjects
Computer science, Computation, Science, Stability (learning theory), Ab initio, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, 010402 general chemistry, computer.software_genre, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Batteries, Simple (abstract algebra), Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Fast ion conductor, Computational methods, Independence (probability theory), Topology (chemistry), Condensed Matter - Materials Science, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Materials Science (cond-mat.mtrl-sci), General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Ranking, Materials chemistry, Data mining, 0210 nano-technology, computer
Abstract

In this paper we develop the stability rules for NASICON-structured materials, as an example of compounds with complex bond topology and composition. By first-principles high-throughput computation of 3881 potential NASICON phases, we have developed guiding stability rules of NASICON and validated the ab initio predictive capability through the synthesis of six attempted materials, five of which were successful. A simple two-dimensional descriptor for predicting NASICON stability was extracted with sure independence screening and machine learned ranking, which classifies NASICON phases in terms of their synthetic accessibility. This machine-learned tolerance factor is based on the Na content, elemental radii and electronegativities, and the Madelung energy and can offer reasonable accuracy for separating stable and unstable NASICONs. This work will not only provide tools to understand the synthetic accessibility of NASICON-type materials, but also demonstrates an efficient paradigm for discovering new materials with complicated composition and atomic structure., Sodium super ionic conductors are a class of promising energy storage materials owing to their high ionic conductivity. Here, the authors conducted high throughput calculations to understand the synthetic accessibility of NASICON-type materials and demonstrate an efficient paradigm for discovering new complex materials.

Published
2021

17. Opportunities and challenges of text mining in materials research

Author

Gerbrand Ceder, Haoyan Huo, Olga Kononova, Tanjin He, Elsa Olivetti, and Amalie Trewartha

Subjects
0301 basic medicine, Data Analysis, Sociology of scientific knowledge, Computer science, Review, 02 engineering and technology, Materials design, computer.software_genre, Field (computer science), Terminology, 03 medical and health sciences, Text mining, Materials Design, lcsh:Science, Class (computer programming), Multidisciplinary, business.industry, 021001 nanoscience & nanotechnology, Data science, Variety (cybernetics), Information extraction, 030104 developmental biology, Computational Materials Science, lcsh:Q, 0210 nano-technology, business, Computing Methodology, computer
Abstract

Research publications are the major repository of scientific knowledge. However, their unstructured and highly heterogenous format creates a significant obstacle to large-scale analysis of the information contained within. Recent progress in natural language processing (NLP) has provided a variety of tools for high-quality information extraction from unstructured text. These tools are primarily trained on non-technical text and struggle to produce accurate results when applied to scientific text, involving specific technical terminology. During the last years, significant efforts in information retrieval have been made for biomedical and biochemical publications. For materials science, text mining (TM) methodology is still at the dawn of its development. In this review, we survey the recent progress in creating and applying TM and NLP approaches to materials science field. This review is directed at the broad class of researchers aiming to learn the fundamentals of TM as applied to the materials science publications., Graphical Abstract, Data Analysis; Computing Methodology; Computational Materials Science; Materials Design

Published
2021

19. Similarity of Precursors in Solid-state Synthesis as Text-Mined from Scientific Literature

Author

Tanjin He, Haoyan Huo, Ziqin Rong, Vahe Tshitoyan, Olga Kononova, Tiago Botari, Wenhao Sun, and Gerbrand Ceder

Subjects
General Chemical Engineering, Solid-state, FOS: Physical sciences, Context (language use), 02 engineering and technology, Scientific literature, 010402 general chemistry, computer.software_genre, 01 natural sciences, physics.data-an, Engineering, Named-entity recognition, Similarity (network science), ESTADO SÓLIDO, Materials Chemistry, Materials, Condensed Matter - Materials Science, business.industry, Materials Science (cond-mat.mtrl-sci), General Chemistry, Chemical similarity, 021001 nanoscience & nanotechnology, cond-mat.mtrl-sci, 0104 chemical sciences, Hierarchical clustering, Substitution model, Physics - Data Analysis, Statistics and Probability, Chemical Sciences, Artificial intelligence, 0210 nano-technology, business, computer, Natural language processing, Data Analysis, Statistics and Probability (physics.data-an)
Abstract

Collecting and analyzing the vast amount of information available in the solid-state chemistry literature may accelerate our understanding of materials synthesis. However, one major problem is the difficulty of identifying which materials from a synthesis paragraph are precursors or are target materials. In this study, we developed a two-step Chemical Named Entity Recognition (CNER) model to identify precursors and targets, based on information from the context around material entities. Using the extracted data, we conducted a meta-analysis to study the similarities and differences between precursors in the context of solid-state synthesis. To quantify precursor similarity, we built a substitution model to calculate the viability of substituting one precursor with another while retaining the target. From a hierarchical clustering of the precursors, we demonstrate that "chemical similarity" of precursors can be extracted from text data. Quantifying the similarity of precursors helps provide a foundation for suggesting candidate reactants in a predictive synthesis model., Comment: Chemistry of Materials (2020)

Published
2020
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20. Text-mined dataset of inorganic materials synthesis recipes

Author

Tanjin He, Olga Kononova, Ziqin Rong, Tiago Botari, Vahe Tshitoyan, Haoyan Huo, Wenhao Sun, and Gerbrand Ceder

Subjects
Statistics and Probability, Data Descriptor, Solid-phase synthesis, Computer science, 02 engineering and technology, Library and Information Sciences, 010402 general chemistry, 01 natural sciences, Chemical synthesis, Chemical equation, Bottleneck, Education, Computational methods, Author Correction, lcsh:Science, Information retrieval, MATERIAIS, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Computer Science Applications, Inorganic materials, lcsh:Q, Statistics, Probability and Uncertainty, 0210 nano-technology, Information Systems
Abstract

Materials discovery has become significantly facilitated and accelerated by high-throughput ab-initio computations. This ability to rapidly design interesting novel compounds has displaced the materials innovation bottleneck to the development of synthesis routes for the desired material. As there is no a fundamental theory for materials synthesis, one might attempt a data-driven approach for predicting inorganic materials synthesis, but this is impeded by the lack of a comprehensive database containing synthesis processes. To overcome this limitation, we have generated a dataset of “codified recipes” for solid-state synthesis automatically extracted from scientific publications. The dataset consists of 19,488 synthesis entries retrieved from 53,538 solid-state synthesis paragraphs by using text mining and natural language processing approaches. Every entry contains information about target material, starting compounds, operations used and their conditions, as well as the balanced chemical equation of the synthesis reaction. The dataset is publicly available and can be used for data mining of various aspects of inorganic materials synthesis., Measurement(s)solid-state synthesis dataTechnology Type(s)natural language processing Machine-accessible metadata file describing the reported data: 10.6084/m9.figshare.9906608

Published
2019

21. Unified Representation of Molecules and Crystals for Machine Learning

Author

Haoyan Huo and Matthias Rupp

Subjects
Chemical Physics (physics.chem-ph), Human-Computer Interaction, Condensed Matter - Materials Science, Artificial Intelligence, Physics - Chemical Physics, many-body tensor representation, machine-learning potential, atomistic simulations, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, ddc:004, Software
Abstract

Accurate simulations of atomistic systems from first principles are limited by computational cost. In high-throughput settings, machine learning can reduce these costs significantly by accurately interpolating between reference calculations. For this, kernel learning approaches crucially require a representation that accommodates arbitrary atomistic systems. We introduce a many-body tensor representation that is invariant to translations, rotations, and nuclear permutations of same elements, unique, differentiable, can represent molecules and crystals, and is fast to compute. Empirical evidence for competitive energy and force prediction errors is presented for changes in molecular structure, crystal chemistry, and molecular dynamics using kernel regression and symmetric gradient-domain machine learning as models. Applicability is demonstrated for phase diagrams of Pt-group/transition-metal binary systems., Final revised version, major update

Published
2017

22. Author Correction: Text-mined dataset of inorganic materials synthesis recipes

Author

Vahe Tshitoyan, Tiago Botari, Ziqin Rong, Haoyan Huo, Tanjin He, Wenhao Sun, Olga Kononova, and Gerbrand Ceder

Subjects
Statistics and Probability, Information retrieval, Computer science, Inorganic materials, lcsh:Q, Library and Information Sciences, Statistics, Probability and Uncertainty, lcsh:Science, Computer Science Applications, Education, Information Systems, Correction text
Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published
2019
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23. Hydrogen-Bond Symmetrization of δ -AlOOH

Author

Yexin Feng, Xin-Zheng Li, Feng Zhu, Xiang Wu, Ying Yuan, Haoyan Huo, Duan Kang, and Qi-Jun Ye

Subjects
Bulk modulus, Materials science, 010504 meteorology & atmospheric sciences, Hydrogen bond, General Physics and Astronomy, Thermodynamics, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Ab initio molecular dynamics, Slab, Symmetrization, Symmetric hydrogen bond, Geothermal gradient, 0105 earth and related environmental sciences
Abstract

The ?-AlOOH can transport water into the deep mantle along cold subducting slab geotherm. We investigate the hydrogen-bond symmetrization behavior of ?-AlOOH under the relevant pressure-temperature condition of the lower mantle using ab initio molecular dynamics (MD). The static symmetrization pressure of 30.0 GPa can be reduced to 17.0 GPa at 300 K by finite-temperature (T) statistics, closer to the experimental observation of ~10.0 GPa. The symmetrization pressure obtained by MD simulation is related to T by P (GPa) + 13.9 (GPa) = 0.01 (GPa/K) × T (K). We conclude that ?-AlOOH in the lower mantle exists with symmetric hydrogen bond from its birthplace, or someplace slightly deeper, to the core-mantle boundary (CMB) along cold subducting slab geotherm. The bulk modulus decreases with T and increases anomalously upon symmetrization: for ?-AlOOH with asymmetric hydrogen bond, and for ?-AlOOH with symmetric hydrogen bond. Our results provide an important insight into the existent form and properties of ?-AlOOH in the lower mantle.

Published
2017
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24. Selective formation of metastable polymorphs in solid-state synthesis.

Author

Yan Zeng, Szymanski, Nathan J., Tanjin He, KyuJung Jun, Gallington, Leighanne C., Haoyan Huo, Bartel, Christopher J., Bin Ouyang, and Ceder, Gerbrand

Subjects
*DENSITY functional theory, *SURFACE energy, *NUCLEATION
Abstract

Metastable polymorphs often result from the interplay between thermodynamics and kinetics. Despite advances in predictive synthesis for solution-based techniques, there remains a lack of methods to design solid-state reactions targeting metastable materials. Here, we introduce a theoretical framework to predict and control polymorph selectivity in solid-state reactions. This framework presents reaction energy as a rarely used handle for polymorph selection, which influences the role of surface energy in promoting the nucleation of metastable phases. Through in situ characterization and density functional theory calculations on two distinct synthesis pathways targeting LiTiOPO4, we demonstrate how precursor selection and its effect on reaction energy can effectively be used to control which polymorph is obtained from solid-state synthesis. A general approach is outlined to quantify the conditions under which metastable polymorphs are experimentally accessible. With comparison to historical data, this approach suggests that using appropriate precursors could enable targeted materials synthesis across diverse chemistries through selective polymorph nucleation. [ABSTRACT FROM AUTHOR]

Published
2024
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