Abstract
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.
| Original language | English |
|---|---|
| Article number | 1900808 |
| Number of pages | 23 |
| Journal | Advanced Science |
| Volume | 6 |
| Issue number | 21 |
| Early online date | 1 Sept 2019 |
| DOIs | |
| Publication status | Published - 6 Nov 2019 |
| MoE publication type | A2 Review article, Literature review, Systematic review |
Funding
The authors thank Nina Granqvist, Kunal Ghosh, Ben Alldritt, Antti M. Rousi, Milica Todorovic', Sven Bossuyt, Miguel Caro, David Gao, Matthias Scheffler, Bryce Meredig, and Heidi Henrickson for insightful discussions and a careful reading of our manuscript. Computing resources from the Aalto Science-IT project and CSC IT Center for Science, Finland, are gratefully acknowledged. This project had received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement number 676580 with The Novel Materials Discovery (NOMAD) Laboratory, a European Center of Excellence, and from the Jenny and Antti Wihuri Foundation. This work was furthermore supported by the Academy of Finland through its Centres of Excellence Programme 2015-2017 under project number 284621, as well as projects 305632, 311012, and 314862. A.S.F. was supported by the World Premier International Research Center Initiative (WPI), MEXT, Japan. This article is part of the Advanced Science 5th anniversary interdisciplinary article series, in which the journal's executive advisory board members highlight top research in their fields.
Keywords
- artificial intelligence
- databases
- data science
- machine learning
- materials
- materials science
- open innovation
- open science
- COMPUTATIONAL MATERIALS SCIENCE
- DENSITY-FUNCTIONAL THEORIES
- MATERIALS INFORMATICS
- QUANTUM-MECHANICS
- NEURAL-NETWORKS
- SEMANTIC WEB
- MACHINE
- DESIGN
- COMBINATORIAL
- INFRASTRUCTURE