Journal of Geological Society of India (Online archive from Vol 1 to Vol 78)

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Near Hydrothermal Alteration of Obsidian Glass: Implications for Long Term Performance Assessments


Affiliations
1 Department of Geology, University of Delhi, Delhi - 110 007, India
2 BETDD, Nuclear Recycle Group, BARC, Mumbai - 400 008, India
     

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Obsidian glass alteration experiments under near hydrothermal conditions were performed to study mechanism and conditions of formation of altered minerals. X-ray diffraction patterns and cell dimensions of the specimens treated at 150, 200 and 300°C (pH = 8.03) revealed appearance of three main minerals - illite (9.5-10 Å), chlorite (7.04 Å) and halloysite (10.25Å). Further increase in the pH favours matrix dissolution with the formation of secondary altered layers. SEM-EDS study show that the alteration causes smoothing of the grain surfaces. These surfaces exhibits etch pits and series of depressions, formed by the process of dissolution. SEM - Back Scattered Electron images of obsidian specimens show thin laminae of smectite, with foliated bulky rims and cellular honeycomb texture, formed by precipitation from the solution as well as by direct transformation of glass during alteration. This mechanism is resulting from the alteration of alkalis by ionic inter-diffusion with H3O+ and H+ and inward diffusion of H2O, leading to free diffusion of silica into solution and then to a local rearrangement of the glass framework. Thus, a direct transformation of glass into clay minerals is the major reaction mechanism as evidenced by the mechanism of glass dissolution and subsequent mineral precipitation.

Keywords

Near Hydrothermal Condition, Geological Repository, Dissolution, Mineral Precipitation.
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  • Near Hydrothermal Alteration of Obsidian Glass: Implications for Long Term Performance Assessments

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Authors

Nishi Rani
Department of Geology, University of Delhi, Delhi - 110 007, India
J. P. Shrivastava
Department of Geology, University of Delhi, Delhi - 110 007, India
R. K. Bajpai
BETDD, Nuclear Recycle Group, BARC, Mumbai - 400 008, India

Abstract


Obsidian glass alteration experiments under near hydrothermal conditions were performed to study mechanism and conditions of formation of altered minerals. X-ray diffraction patterns and cell dimensions of the specimens treated at 150, 200 and 300°C (pH = 8.03) revealed appearance of three main minerals - illite (9.5-10 Å), chlorite (7.04 Å) and halloysite (10.25Å). Further increase in the pH favours matrix dissolution with the formation of secondary altered layers. SEM-EDS study show that the alteration causes smoothing of the grain surfaces. These surfaces exhibits etch pits and series of depressions, formed by the process of dissolution. SEM - Back Scattered Electron images of obsidian specimens show thin laminae of smectite, with foliated bulky rims and cellular honeycomb texture, formed by precipitation from the solution as well as by direct transformation of glass during alteration. This mechanism is resulting from the alteration of alkalis by ionic inter-diffusion with H3O+ and H+ and inward diffusion of H2O, leading to free diffusion of silica into solution and then to a local rearrangement of the glass framework. Thus, a direct transformation of glass into clay minerals is the major reaction mechanism as evidenced by the mechanism of glass dissolution and subsequent mineral precipitation.

Keywords


Near Hydrothermal Condition, Geological Repository, Dissolution, Mineral Precipitation.

References