Litcius/Paper detail

Discovery of electrochemically induced grain boundary transitions

Jiuyuan Nie, Chongze Hu, Qizhang Yan, Jian Luo

2021Nature Communications51 citationsDOIOpen Access PDF

Abstract

Abstract Electric fields and currents, which are used in innovative materials processing and electrochemical energy conversion, can often alter microstructures in unexpected ways. However, little is known about the underlying mechanisms. Using ZnO-Bi 2 O 3 as a model system, this study uncovers how an applied electric current can change the microstructural evolution through an electrochemically induced grain boundary transition. By combining aberration-corrected electron microscopy, photoluminescence spectroscopy, first-principles calculations, a generalizable thermodynamic model, and ab initio molecular dynamics, this study reveals that electrochemical reduction can cause a grain boundary disorder-to-order transition to markedly increase grain boundary diffusivities and mobilities. Consequently, abruptly enhanced or abnormal grain growth takes place. These findings advance our fundamental knowledge of grain boundary complexion (phase-like) transitions and electric field effects on microstructural stability and evolution, with broad scientific and technological impacts. A new method to tailor the grain boundary structures and properties, as well as the microstructures, electrochemically can also be envisioned.

Topics & Concepts

Grain boundaryMaterials scienceElectric fieldChemical physicsElectrochemistryMicrostructureCondensed matter physicsBoundary (topology)Grain boundary diffusion coefficientCurrent (fluid)Electric currentField (mathematics)Grain boundary strengtheningElectronGrain growthGrain sizeNanotechnologyAb initioDensity functional theoryAb initio quantum chemistry methodsEngineering physicsMetallurgyWork (physics)Boundary value problemMolecular dynamicsElectronic structureChemical stabilityStability (learning theory)Current densityPhotoluminescenceElectrochemical potentialMicrostructure and mechanical propertiesAnodic Oxide Films and NanostructuresElectromagnetic Effects on Materials