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Quantifying the regime of thermodynamic control for solid-state reactions during ternary metal oxide synthesis

Nathan J. Szymanski, Young‐Woon Byeon, Yingzhi Sun, Yan Zeng, Jianming Bai, Martin Kunz, Dong‐Min Kim, Brett A. Helms, Christopher J. Bartel, Haegyeom Kim, Gerbrand Ceder

2024Science Advances16 citationsDOIOpen Access PDF

Abstract

The success of solid-state synthesis often hinges on the first intermediate phase that forms, which determines the remaining driving force to produce the desired target material. Recent work suggests that when reaction energies are large, thermodynamics primarily dictates the initial product formed, regardless of reactant stoichiometry. Here, we validate this principle and quantify its constraints by performing in situ characterization on 37 pairs of reactants. These experiments reveal a threshold for thermodynamic control in solid-state reactions, whereby initial product formation can be predicted when its driving force exceeds that of all other competing phases by ≥60 milli-electron volt per atom. In contrast, when multiple phases have a comparable driving force to form, the initial product is more often determined by kinetic factors. Analysis of the Materials Project data shows that 15% of possible reactions fall within the regime of thermodynamic control, highlighting the opportunity to predict synthesis pathways from first principles.

Topics & Concepts

Work (physics)Ternary operationThermodynamicsStoichiometryOxidePhase (matter)Characterization (materials science)Kinetic energyMaterials scienceAtom (system on chip)Thermodynamic equilibriumChemical physicsChemistryNanotechnologyPhysical chemistryPhysicsComputer scienceClassical mechanicsMetallurgyProgramming languageOrganic chemistryEmbedded systemMachine Learning in Materials ScienceElectronic and Structural Properties of OxidesAdvanced Materials Characterization Techniques
Quantifying the regime of thermodynamic control for solid-state reactions during ternary metal oxide synthesis | Litcius