Abstract
Abstract Determination of the oxidation state and coordination geometry of iron in Fe-bearing minerals expands our knowledge obtained by standard mineralogical characterization. It provides information that is crucial in assessing the potential of minerals to interact with their surrounding environment and to generate reactive oxygen species, which can disrupt the normal function of living organisms. Aberration-corrected scanning transmission electron microscopy dual-electron energy-loss spectroscopy (acSTEM Dual-EELS) has only rarely been applied in environmental and medical mineralogy, but it can yield data that are essential for the description of near-surface and surface mechanisms involved in many environmental and health-related processes. In this study, we have applied the energy loss near-edge structure (ELNES) and L2,3 white-line intensity-ratio methods using both the universal curve and progressively larger integrating windows to verify their effectiveness in satisfactorily describing the valence state of iron at amosite grain boundaries, and, at the same time, to estimate thickness in the same region of interest. The average valence state obtained from acSTEM Dual-EELS and from a simplified geometrical model were in good agreement, and within the range defined by the bulk and the measured surface-valence states. In the specific case presented here, the use of the universal curve was most suitable in defining the valence state of iron at amosite grain boundaries. The study of ELNES revealed an excellent correspondence with the valence state determined by the L2,3 white-line intensity-ratio method through the use of the universal curve, and it seems that the spectra carry some information regarding the coordination geometry of Fe. The combination of visual examination, reconstruction of the grain boundaries through a simple geometrical model, and Dual-EELS investigation is a powerful tool for characterizing the grain boundaries of hazardous minerals and foreseeing their potential activity in an organism, with the possibility to describe toxic mechanisms in a stepwise fashion.
Highlights
The valence state of Fe in members of the amphibole supergroup plays an important role when elucidating mineralogical and geological history since it can be influenced by multiple geochemical reactions under a wide range of conditions (Cavé et al 2006)
The average valence state obtained from aberration-corrected scanning transmission electron microscopy (acSTEM) Dual-EELS and from a simplified geometrical model were in good agreement, and within the range defined by the bulk and the measured surface-valence states
The valence state determined on the amphibole region of interest (ROI) using the universal curve represents the best match with regard to the intensity and shape of the L3-edge energy loss near-edge structure (ELNES) and was used for further evaluations of ELNES spectra
Summary
The valence state of Fe in members of the amphibole supergroup plays an important role when elucidating mineralogical and geological history since it can be influenced by multiple geochemical reactions under a wide range of conditions (Cavé et al 2006). The use of aberration-corrected scanning transmission electron microscopy (acSTEM) and dual electron energy loss spectroscopy (Dual-EELS) allows for simultaneous collection of two spectra at different energy loss ranges in a specific ROI on individual particles. This translates to an immediate alignment of the zero-loss peak and, side-steps the need to collect two consecutive spectra on the same sample area to perform the alignment (Potapov and Schryvers 2004), resulting in a shorter exposure of the ROI to the electron beam and reducing potential electron-beam damages and operational time. Application of Dual-EELS has a great advantage compared to conventional EELS because it eliminates the need for measuring the low-loss and high-loss spectra consecutively, allowing for in-loco determination of the ROI thickness simultaneously with its valence state
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