Author(s)

Kevin Ortner

Affiliation(s)

University of British Columbia, Vancouver, British Columbia V6T 1Z2, Canada.

Corresponding Author

Kevin Ortner

ABSTRACT

Materials genome integrates high-throughput computing, high-throughput preparation, high-throughput detection and database systems of materials. It is a "paradigm revolution" in materials research and development. With its profound scientific connotation and significant application potential, it will accelerate New materials discovery and applications. This article focuses on the use of materials genome in the research and development of new energy materials to shorten the "discovery-development-production-application" cycle of new energy materials. It introduces the internationally representative Materials Project and OQMD two material genome platforms, as well as some important the application of materials genome computing technologies, such as material conformation characterization, high-throughput computing and screening, machine learning, neural network technology, optimization algorithms and new high-throughput preparation and characterization technologies, in the research and development of new energy materials, and the next step the development of materials genome puts forward prospects, such as developing high-precision high-throughput computing, using artificial intelligence to develop high-throughput experimental systems and platforms, generating material big data, and making full use of material big data through intelligent computing to create computing and experiments. The integrated materials genome big data artificial intelligence system accelerates the discovery and application of new energy materials.

KEYWORDS

Materials genome; New energy materials; High-throughput computing; High-throughput experiment

CITE THIS PAPER

Kevin Ortner. Application progress of materials genome technology in the field of new energy materials. World Journal of Materials Science. 2024, 2(1): 11-20. DOI: 10.61784/wjms240168.

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