Effects of heating on fire opal and diaspore from Turkey
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2010
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Abstract
Fire opal (SiO2·nH2O) and diaspore [Al(OH)O] are two different precious and rare mineral species with high water content. While these species are being cut and polished to make gems, defect-induced weaknesses such as fragility, splintering, and cracking become apparent since the temperature of the mineral species may be increased to high temperatures during the process. These deformations may be broadly related to water loss (molecular (H2O) and hydroxyl (OH) group) and transformation of the base building components and/or inclusion minerals. In this study, thermal properties and thermal stability as dehydratial behaviors of both gem quality fire opal (SiO2·nH2O) from the Şaphane region (Kütahya, Turkey) and gem quality diaspore (AlOHO) from the Milas region (Muǧla, Turkey), including some associated mineral inclusions, were studied by means of X-ray diffraction (XRD), X-ray fluorescence (XRF), Fourier transform-Infrared absorption (FTIR) spectroscopy and thermal analysis (DTA/TGA). During heating to 1400 °C, DTA/TGA patterns indicated that the weight losses of the fire opal and diaspore were due to the water loss only, and that these losses occur in the temperature ranges between about 342 and 722 °C in fire opal, and between about 592 and 718 °C in diaspore. In addition, after making some corrections concerning the mass gain observed, being due to the drift with buoyancy effect of the atmosphere, in their TGA curves, the fire opal shows a mass loss of 7.942%, and one distinctive sharp endotherm at 1089.99 °C and seven weaker endotherms, whereas the diaspore shows a mass loss of about 13.826%, and one distinctive sharpest endotherm at 650.47 °C and four weaker endotherms. © 2010 Elsevier B.V. All rights reserved.
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Absorption spectroscopy , Buoyancy , Cements , Fourier transform infrared spectroscopy , Gems , Heating , Inclusions , Minerals , Refractory materials , Silicate minerals , Silicon compounds , Thermoanalysis , Thermodynamic properties , Water content , X ray diffraction , X ray diffraction analysis , Buoyancy effect , Dehydratial behaviors , DTA/TGA analyses , FTIR , High temperature , High water content , Mass gain , Mass loss , Mineral inclusions , Mineral species , Temperature range , TGA curves , Thermal analysis , Thermal properties , Thermal stability , Water loss , Weight loss , X ray fluorescence , XRD , Fires