Uncovering compounds by synergy of cluster expansion and high-throughput methods.
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Predicting from first-principles calculations whether mixed metallic elements phase-separate or form ordered structures is a major challenge of current materials research. It can be partially addressed in cases where experiments suggest the underlying lattice is conserved, using cluster expansion (CE) and a variety of exhaustive evaluation or genetic search algorithms. Evolutionary algorithms have been recently introduced to search for stable off-lattice structures at fixed mixture compositions. The general off-lattice problem is still unsolved. We present an integrated approach of CE and high-throughput ab initio calculations (HT) applicable to the full range of compositions in binary systems where the constituent elements or the intermediate ordered structures have different lattice types. The HT method replaces the search algorithms by direct calculation of a moderate number of naturally occurring prototypes representing all crystal systems and guides CE calculations of derivative structures. This synergy achieves the precision of the CE and the guiding strengths of the HT. Its application to poorly characterized binary Hf systems, believed to be phase-separating, defines three classes of alloys where CE and HT complement each other to uncover new ordered structures.
Published Version (Please cite this version)10.1021/ja9105623
Publication InfoLevy, O; Hart, GL; & Curtarolo, S (2010). Uncovering compounds by synergy of cluster expansion and high-throughput methods. J Am Chem Soc, 132(13). pp. 4830-4833. 10.1021/ja9105623. Retrieved from https://hdl.handle.net/10161/4053.
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Professor in the Department of Mechanical Engineering and Materials Science
RESEARCH FIELDS Nanoscale Science of Energy Computational materials science Nanotube growth characterization Alloy theory Superlubricity on quasicrystals Superconductivity in Metal borides Genetic Approaches to QM Predictions of Materials Structures Materials for Nuclear Detection The research is multidisciplinary and makes use of state of the art techniques from fields like materials science, chemis