Your search keyword '"Krivovichev, Sergey V."' showing total 2 results

1. High-temperature Fe oxidation coupled with redistribution of framework cations in lobanovite, K Na(Fe Mg Na)Ti (Si O ) O (OH) – the first titanosilicate case

Author

Zhitova, Elena S., Zolotarev, Andrey A., Hawthorne, Frank C., Krivovichev, Sergey V., Yakovenchuk, Viktor N., and Goncharov, Alexey G.

Subjects

Bond strength, Chemistry, Crystal chemistry, Metals and Alloys, Atmospheric temperature range, engineering.material, 010502 geochemistry & geophysics, 010403 inorganic & nuclear chemistry, 01 natural sciences, Atomic and Molecular Physics, and Optics, Thermal expansion, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Crystallography, Astrophyllite, Octahedron, Materials Chemistry, engineering, Dehydrogenation, Redistribution (chemistry), 0105 earth and related environmental sciences

Abstract

The high-temperature (HT) behaviour of lobanovite, K Na(Fe Mg Na)Ti (Si O ) O (OH) , was studied using powder X-ray diffraction in the temperature range 25–1000°C and single-crystal X-ray diffraction of 17 crystals quenched from different temperatures. HT iron oxidation associated with dehydroxylation starts at 450°C, similar to other ferrous-hydroxy-rich heterophyllosilicates such as astrophyllite and bafertisite. A prominent feature of lobanovite HT crystal chemistry is the redistribution of Fe and Mg+Mn cations over the (2), (3), (4) sites of the octahedral ( ) layer that accompanies iron oxidation and dehydroxylation. This HT redistribution of cations has not been observed in titanosilicates until now, and seems to be triggered by the need to maintain bond strengths at the apical oxygen atom of the TiO pyramid in the heteropolyhedral ( ) layer during oxidation–dehydroxylation. Comparison of the HT behaviour of lobanovite with five-coordinated Ti and astrophyllite with six-coordinated Ti shows that the geometry of the Ti polyhedron plays a key role in the HT behaviour of heterophyllosilicates. The thermal expansion, geometrical changes and redistribution of site occupancies which occur in lobanovite under increasing temperature are reported. A brief discussion is given of minerals in which the cation ordering (usually for Fe and Mg) occurs together with iron oxidation–dehydroxylation at elevated temperatures: micas, amphiboles and tourmalines. Now this list is expanded by the inclusion of titanosilicate minerals.

Published

2019

2. The complex mechanism of Ti4+ incorporation into litidionite from the Somma–Vesuvius volcano, Italy

Author

Giuseppina Balassone, Taras L. Panikorovskii, Annamaria Pellino, Ayya V. Bazai, Vladimir N. Bocharov, Sergey V. Krivovichev, Carmela Petti, Piergiulio Cappelletti, Nicola Mondillo, Balassone, Giuseppina, Panikorovskii, Taras L., Pellino, Annamaria, Bazai, Ayya V., Bocharov, Vladimir N., Krivovichev, Sergey V., Petti, Carmela, Cappelletti, Piergiulio, and Mondillo, Nicola

Subjects

Ti-litidionite, Somma–Vesuvius, Ti incorporation, crystal structure, Geochemistry and Petrology

Abstract

For this study, the rare Cu-bearing silicate fumarolic assemblages from the Somma–Vesuvius volcano, Italy, characterised by the rare mineral litidionite, CuKNaSi4O10, were investigated. We report new data about Cu- and Ti-bearing phases found in these mineralisations, in which Ti-bearing litidionite occurs together with kamenevite, perovskite and rutile. Ti-bearing litidionite appears on the latest stages of partial crystallisation of Ti-bearing silica glass. Incorporation of Ti4+ into the litidionite crystal structure was investigated in detail. The Raman spectra of Ti-bearing litidionite contains an intense band at 597 cm−1 related to anti-symmetric bending vibrations of Si‒O bonds or overlapping stretching vibrations of Ti‒O bonds. The bands in the range 350‒500 cm−1 correspond to symmetric bending vibrations of O‒Si‒O bonds and overlapping stretching vibrations of Ti‒O bonds. The crystal structure of Ti-litidionite has been refined in the P$\bar{1}$ space group, a = 6.9699(7), b = 7.9953(10), c = 9.8227(10) Å, α = 105.186(9), β = 99.458(8) and γ = 114.489(10) to R1 = 0.064 for 1726 unique observed reflections. The refinement of the site-occupation factors confirmed the presence of Ti at a five-coordinated M site. The mean bond distance of 2.125 Å for the M site agrees with its refined occupancy (Ti0.32Cu0.30Ca0.29Fe0.09)1.00. The incorporation of Ti into the litidionite structure is accompanied by the complex heteropolyhedral substitution according to the scheme VTi4+ + VII–VIII□ + IVAl3+ ↔ VCu2+ + VII-VIII(Na,K)+ + IVSi4+. Two possible configurations for the phase with maximal TiO2 content (12.06 wt.% or 0.56 Ti apfu) CuTiK□Na2Si7AlO20 (Z = 1) or CuTiK2Na□Si7AlO20 (Z = 1) have been proposed.

Published

2022