Chemical diversity in molecular orbital energy predictions with kernel ridge regression

Stuke, Annika; Todorović, Milica; Rupp, Matthias; Künkel, Christian; Ghosh, Kunal; Himanen, Lauri; Rinke, Patrick

doi:10.1063/1.5086105

Cited by 75 publications

(114 citation statements)

References 71 publications

(110 reference statements)

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“…[17] Supervised learning applies in situations where a machine learning model is trained on input-output pairs from a real process to produce optimal outputs for unseen inputs. Typical applications are predictions of physical properties (like formation energies [200][201][202] or molecular properties [203][204][205][206][207] ) given the input features of a material or process (e.g., geometry, physical properties, external conditions).…”

Section: Introduction To Machine Learningmentioning

confidence: 99%

Data‐Driven Materials Science: Status, Challenges, and Perspectives

et al. 2019

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Data‐driven science is heralded as a new paradigm in materials science. In this field, data is the new resource, and knowledge is extracted from materials datasets that are too big or complex for traditional human reasoning—typically with the intent to discover new or improved materials or materials phenomena. Multiple factors, including the open science movement, national funding, and progress in information technology, have fueled its development. Such related tools as materials databases, machine learning, and high‐throughput methods are now established as parts of the materials research toolset. However, there are a variety of challenges that impede progress in data‐driven materials science: data veracity, integration of experimental and computational data, data longevity, standardization, and the gap between industrial interests and academic efforts. In this perspective article, the historical development and current state of data‐driven materials science, building from the early evolution of open science to the rapid expansion of materials data infrastructures are discussed. Key successes and challenges so far are also reviewed, providing a perspective on the future development of the field.

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Section: Introduction To Machine Learningmentioning

confidence: 99%

Data‐Driven Materials Science: Status, Challenges, and Perspectives

et al. 2019

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“…[33][34][35] Our study indicated that this machine-learning strategies may provide OFET researchers supporting details to fine-tune the electronic structure and thus the charge transport property of the n-type organic materials. [33][34][35] Our study indicated that this machine-learning strategies may provide OFET researchers supporting details to fine-tune the electronic structure and thus the charge transport property of the n-type organic materials.…”

mentioning

confidence: 77%

Machine Learning for Understanding the Relationship between the Charge Transport Mobility and Electronic Energy Levels for n‐Type Organic Field‐Effect Transistors

Lee

2019

Adv Elect Materials

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Organic field‐effect transistors (OFETs) have received considerably more attention than inorganic‐based field‐effect transistors for use in next generation of organic circuits. There are a number of variables, for example, the ordering of the OFETs, their energy levels, and the material used for source/drain electrodes, that influence the magnitude of charge transport mobility. Importantly, a suitable energy level match between highest occupied molecular orbital (HOMO) or lowest unoccupied molecular orbital (LUMO) energy level and work function of the electrodes may have a large influence on the measured mobility. An informatics approach, specifically use of machine learning, is proposed for charge transport mobility prediction. Gradient Boosting and Random Forest regression algorithms are used to model previous experimental datasets and HOMO and LUMO energy levels of n‐type materials are optimized using expected machine‐learning methods. The results reveal that Random Forest model benefits the functional analysis of n‐type OFETs in three ways: 1) it provides better understanding of current n‐type organic materials, 2) it may guide the choice of n‐type organic materials and conducting electrodes, and 3) it measures the tradeoffs between the charge transport mobility and electronic energy levels for n‐type OFETs.

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“…dictions for solids [5][6][7][8], accelerated molecular property prediction [9][10][11], creation of new force-fields based on quantum mechanical training data [12][13][14][15][16][17][18][19], search for catalytically active sites in nanoclusters [20][21][22][23][24] and efficient optimization of complex structures [25][26][27]. Atomistic machine learning establishes a relationship between the atomic structure of a system and its properties.…”

Section: Introductionmentioning

confidence: 99%

DScribe: Library of descriptors for machine learning in materials science

Himanen

Jäger

Morooka

et al. 2020

Computer Physics Communications

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DScribe is a software package for machine learning that provides popular feature transformations ("descriptors") for atomistic materials simulations. DScribe accelerates the application of machine learning for atomistic property prediction by providing user-friendly, off-the-shelf descriptor implementations. The package currently contains implementations for Coulomb matrix, Ewald sum matrix, sine matrix, Many-body Tensor Representation (MBTR), Atom-centered Symmetry Function (ACSF) and Smooth Overlap of Atomic Positions (SOAP). Usage of the package is illustrated for two different applications: formation energy prediction for solids and ionic charge prediction for atoms in organic molecules. The package is freely available under the open-source Apache License 2.0.

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Chemical diversity in molecular orbital energy predictions with kernel ridge regression

Cited by 75 publications

References 71 publications

Data‐Driven Materials Science: Status, Challenges, and Perspectives

Data‐Driven Materials Science: Status, Challenges, and Perspectives

Machine Learning for Understanding the Relationship between the Charge Transport Mobility and Electronic Energy Levels for n‐Type Organic Field‐Effect Transistors

DScribe: Library of descriptors for machine learning in materials science

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