Abstract
Differently colored natural Brazilian andalusite crystals heat-treated under reducing and oxidizing conditions were analyzed by optical spectroscopy. The intensity of a broad intense band at around 20,500 cm−1 in the optical absorption spectra of all color zones of the sample is proportional to the product of Ti- and Fe-concentrations and herewith proves its attribution to electronic Fe2+/Ti4+ IVCT transition. The band is strictly E||c-polarized, causing an intense red coloration of the samples in this polarization. The polarization of the Fe2+/Ti4+ IVCT band in andalusite, E||c, shows that the electronic charge-transfer process takes place in Al–O octahedral groups that share edges with neighbors on either side, forming chains parallel to the c-axis of the andalusite structure. Under thermal treatments in air, the first noticeable change is some intensification of the band at 800°C. However, at higher temperatures its intensity decreases until it vanishes at 1,000°C in lightly colored zones and 1,100°C in darkly colored ones. Under annealing in reducing conditions at 700 and 800°C, the band also slightly increases and maintains its intensity at treatments at higher temperatures up to 1,000°C. These results demonstrate that weakening and disappearance of the Fe2+/Ti4+ IVCT band in spectra of andalusite under annealing in air is caused by oxidization of Fe2+ to Fe3+ in IVCT Fe2+/Ti4+-pairs. Some intensification of the band at 800°C is, most probably, due to thermally induced diffusion of Fe2+ and Ti4+ in the structure that leads to aggregation of “isolated” Ti4+ and Fe2+ ions into Fe2+–Ti4+-pairs. At higher temperatures, the competing process of Fe2+ → Fe3+ oxidation overcomes such “coupling” and the band continues to decrease. The different thermal stability of the band in lightly and darkly colored zones of the samples evidence some self-stabilization over an interaction of Fe2+/Ti4+-pairs involved in IVCT process.
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Notes
Distinct marks of material evaporation produced by ICP on the polished surface of the sample were further used as targets for repeating spectroscopic measurements in the chosen areas after a series of subsequent annealing experiments.
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Acknowledgments
Reiner Schulz, Potsdam, helped with thermal treatments of the samples. Two reviewers, Ulf Hålenius and an anonymous reviewer, gave a number of helpful comments and suggestions that significantly improved the paper. The anonymous reviewer also made a lot of changes in the text to improve the language. The German Science Foundation, Bonn-Bad Godesberg, generously supported this work through traveling grant (KO 1260/12-1) to MNT. We are grateful to these individual and institution for their help.
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Taran, M.N., Koch-Müller, M. Optical absorption of electronic Fe–Ti charge-transfer transition in natural andalusite: the thermal stability of the charge-transfer band. Phys Chem Minerals 38, 215–222 (2011). https://doi.org/10.1007/s00269-010-0397-9
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DOI: https://doi.org/10.1007/s00269-010-0397-9