Formation of a Nanocrystalline Layer on the Surface of Stone Wool Fibers

In the present paper, we report a simple approach for creating a nanocrystalline layer on the surface of stone wool fibers (SWFs) with a basalt-like composition. The approach is based on a preoxidation process of the SWFs in atmospheric air at a temperature around the glass transition temperature (Tg) for various durations. During preoxidation, the network-modifying ions diffuse from the interior toward the surface of SWFs and react with oxygen on the surface to form oxides. This diffusion process is accompanied by an inward diffusion of electron holes via the oxidation process of Fe2+ to Fe3+. It is found that the diffusion of Mg2+ is dominant in the overall diffusion process. The main phase of the nanocrystalline layer is identified to be periclase (MgO) crystals. The thickness of the nanocrystalline layer can be varied by adjusting the temperature and the duration of preoxidation. The nanocrystalline layer plays a significant role in enhancing the high-temperature stability of the SWFs.

[1]  M. Toplis,et al.  An Experimental Study of the Influence of Oxygen Fugacity on Fe-Ti Oxide Stability, Phase Relations, and Mineral—Melt Equilibria in Ferro-Basaltic Systems , 1995 .

[2]  Y. Yue,et al.  Redox behaviour of iron bearing glass fibres during heat treatment under atmospheric conditions , 2005 .

[3]  R. Cooper,et al.  The mechanism of oxidation of a basaltic glass: Chemical diffusion of network-modifying cations , 1997 .

[4]  Y. Yue,et al.  Fictive temperature, cooling rate, and viscosity of glasses. , 2004, The Journal of chemical physics.

[5]  D. Burkhard Crystallization and Oxidation of Kilauea Basalt Glass: Processes during Reheating Experiments , 2001 .

[6]  Y. Yue,et al.  Crystallization in stone wool fibres , 2007 .

[7]  A. Karamanov,et al.  Influence of Fe3+/Fe2+ Ratio on the Crystallization of Iron‐Rich Glasses Made with Industrial Wastes , 2000 .

[8]  P. Liljeroth,et al.  Electron-conducting quantum dot solids: novel materials based on colloidal semiconductor nanocrystals. , 2005, Chemical Society reviews.

[9]  P. Richet,et al.  Silicate glasses and melts : properties and structure , 2005 .

[10]  P. O’Brien,et al.  Strategies for the Scalable Synthesis of Quantum Dots and Related Nanodimensional Materials , 2005 .

[11]  J. M. Parker,et al.  Redox and clustering of iron in silicate glasses , 1999 .

[12]  G. H. Frischat,et al.  A method to determine concentration-distance profiles of corroded glass fibers , 1995 .

[13]  R. Rawlings,et al.  Effect of the redox state and concentration of iron on the crystallization behavior of iron-rich aluminosilicate glasses , 2005 .

[14]  M. Pileni The role of soft colloidal templates in controlling the size and shape of inorganic nanocrystals , 2003, Nature materials.

[15]  R. Cooper,et al.  Dynamic oxidation of a Fe2+-bearing calcium–magnesium–aluminosilicate glass: the effect of molecular structure on chemical diffusion and reaction morphology , 2000 .

[16]  A. Karamanov,et al.  Crystallization phenomena in iron-rich glasses , 2001 .

[17]  C. Ronchi,et al.  Melting Point of MgO. , 2001 .