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Abstract
Systematic control and design of solid-state chemical reactions is required for modifying materials properties and in novel synthesis. Understanding chemical dynamics at the nanoscale is therefore essential to reveal the key reactive pathways. Herein, we combine focused ion beam-scanning electron microscopy (FIB-SEM) and time-of-flight secondary ion mass spectrometry (TOF-SIMS) to track the migration of sodium from a borate coating to the oxide scale during in situ hot corrosion testing. We map the changing distribution of chemical elements and compounds from 50 to 850 °C to reveal how sodium diffusion induces corrosion. The results are validated by in situ X-ray diffraction and post-mortem TOF-SIMS. We additionally retrieve the through-solid sodium diffusion rate by fitting measurements to a Fickian diffusion model. This study presents a step-change in analysing microscopic diffusion mechanics with high chemical sensitivity and selectivity, a widespread analytical challenge that underpins the defining rates and mechanisms of solid-state reactions.
Supplementary materials
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TOC
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Graphical Abstract showing in-situ TOF-SIMS heating analysis for direct tracking of hot corrosion reactions between sodium borate glass coatings and oxide scale, induced by the boron-decoupled diffusion of sodium.
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Supporting Information
Description
Experimental details; in-situ SEM heating results; lateral resolution determination; evaluation of beam conditions for TOF-SIMS analysis; demonstration of multivariate data analysis and results for the TOF-SIMS dataset at 250, 350, 420, and 580 °C; note on the effect of ion beam irradiation on chemical transport; in-situ XRD heating results, the mass spectra extracted from the coating; the loosely-packed oxide layer; and the continuous oxide layer for individual temperatures; note on established Fickian diffusion model and evaluation of the goodness-of-fit for the model; diffusion coefficient exported for individual temperatures.
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Supplementary Video
Description
Diffusion of sodium from the coating to the oxide scale at 260-400 °C
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