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Predicting Nonequilibrium Patterns beyond Thermodynamic Concepts: Application to Radiation-Induced Microstructures

L. Lunéville, Philippe Garcia, David Siméone

2020Physical Review Letters11 citationsDOIOpen Access PDF

Abstract

In this work, we derive an analytical model to predict the appearance of all possible radiation-induced steady states and their associated microstructures in immiscible A_{c[over ¯]}B_{1-c[over ¯]} alloys, an example of a nonequilibrium dynamical system. This model is assessed against numerical simulations and experimental results which show that different microstructures characterized by the patterning of A-rich precipitates can emerge under irradiation. We demonstrate that the steady-state microstructure is governed by irradiation conditions and also by the average initial concentration of the alloy c[over ¯]. Such a dependence offers new leverage for tailoring materials with specific microstructures overcoming limitations imposed by the equilibrium thermodynamic phase diagram.

Topics & Concepts

Non-equilibrium thermodynamicsMicrostructureMaterials sciencePhase diagramThermodynamicsAlloyWork (physics)Thermodynamic equilibriumLeverage (statistics)IrradiationRadiationStatistical physicsPhase (matter)PhysicsCondensed matter physicsOpticsMetallurgyNuclear physicsQuantum mechanicsComputer scienceMachine learningSolidification and crystal growth phenomenaMicrostructure and mechanical propertiesHigh-pressure geophysics and materials
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