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Crystal dissolution by particle detachment

Guomin Zhu, Benjamin A. Legg, Michel Sassi, Xinran Liang, Meirong Zong, Kevin M. Rosso, James J. De Yoreo

2023Nature Communications23 citationsDOIOpen Access PDF

Abstract

Abstract Crystal dissolution, which is a fundamental process in both natural and technological settings, has been predominately viewed as a process of ion-by-ion detachment into a surrounding solvent. Here we report a mechanism of dissolution by particle detachment (DPD) that dominates in mesocrystals formed via crystallization by particle attachment (CPA). Using liquid phase electron microscopy to directly observe dissolution of hematite crystals — both compact rhombohedra and mesocrystals of coaligned nanoparticles — we find that the mesocrystals evolve into branched structures, which disintegrate as individual sub-particles detach. The resulting dissolution rates far exceed those for equivalent masses of compact single crystals. Applying a numerical generalization of the Gibbs-Thomson effect, we show that the physical drivers of DPD are curvature and strain inherently tied to the original CPA process. Based on the generality of the model, we anticipate that DPD is widespread for both natural minerals and synthetic crystals formed via CPA.

Topics & Concepts

DissolutionCrystallizationParticle (ecology)Crystal (programming language)Materials scienceChemical engineeringCurvatureParticle sizeNanoparticleChemical physicsCrystallographyIonNanotechnologyChemistryGeologyComputer scienceOrganic chemistryOceanographyEngineeringProgramming languageMathematicsGeometryIron oxide chemistry and applicationsGeological and Geochemical AnalysisClay minerals and soil interactions
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