Sage Journals: Discover world-class research

Abstract

The composition of glasses used in glass-ionomer cements affects their leaching behavior and hence the properties of the cement. The aim of this study was to correlate the composition and leaching behavior of these glasses with their infrared absorption characteristics. The wavenumber of the absorption band of the Si-O asymmetric stretching vibration ῡ_AS shifts to a higher value with decreasing content of mono- and bivalent cations in the glass. This effect can be ascribed to the influence of these extraneous ions on the glass network order and connectivity. Preferential leaching of these ions induces an increase of ῡ_AS and a general modification of the band profile. The results can be correlated with the x-ray diffraction characteristics of the glass.

A decrease in the Si-O-Si angle could be caused by a decrease in the distortions in the (arrangement of the) SiO₄ tetrahedra; the tetrahedra as well as their arrangement can be distorted.

Get full access to this article

View all access options for this article.

References

Davis KM, Tomozawa M -1996-. An infrared spectroscopic study of water-related species in silica glasses. J Non-Cryst Sol201:177–198.

De Maeyer EA, Verbeeck RM -2001-. X-ray diffraction study of acid-degradable glasses. J Dent Res80:1764–1767.

De Maeyer EA, Verbeeck RM, Vercruysse CW -1998-. Reactivity of fluoride-containing calcium aluminosilicate glasses used in dental glass-ionomer cements. J Dent Res77:2005–2011.

De Maeyer EA, Verbeeck RM, Vercruysse CW -1999-. Stoichiometry of the leaching process of fluoride-containing aluminosilicate glass-ionomer glasses. J Dent Res78:1312–1318.

Dorsey GA -1968-. Far infrared absorption of hydrous and anhydrous aluminas. Anal Chem40:971–972.

Efimov AM -1996-. Quantitative IR spectroscopy: applications to studying glass structure and properties. J Non-Cryst Sol203:1–11.

Farmer VC, Fraser AR, Tait JM -1979-. Characterization of the chemical structures of natural and synthetic aluminosilicate gels and sols by infrared spectroscopy. Geoch et Cosmoch Acta43:1417–1420.

Hill RG, Goat C, Wood D -1992-. Thermal analysis of a SiO₂-Al₂O₃-CaO-CaF₂ glass. J Am Ceram Soc75:778–785.

Matsuya S, Matsuya Y, Yamamoto Y, Yamane M -1984-. Erosion process of a glass ionomer cement in organic acids. Dent Mater J3:210–219.

10.

Matsuya S, Maeda T, Ohta M -1996-. IR and NMR analyses of hardening and maturation of glass-ionomer cement. J Dent Res75:1920–1927.

11.

Miller JM, Lakshmi LJ -1998-. Spectroscopic characterization of sol-gel-derived mixed oxides. J Phys Chem B102:6465–6470.

12.

Nicholson JW -1998-. Chemistry of glass-ionomer cements: a review. Biomaterials19:485–494.

13.

Poenar DP, van der Puil N, French PJ, Wolffenbuttel RF -1996-. Infrared spectroscopic analysis of phosphosilicate glass films for micromachining. J Electrochem Soc143:968–973.

14.

Shelby JE -1997-. Introduction to glass science and technology. Cambridge: The Royal Society of Chemistry.

15.

Soda R -1961-. Infrared absorption spectra of quartz and some other silica modification. Bull Chem Soc Jpn34:1491–1495.

16.

Svehla G, editor -1976-. Comprehensive analytical chemistry. Vol. VI. Analytical infrared spectroscopy. Amsterdam: Elsevier Scientific Publishing Co.

17.

Wasson EA, Nicholson JW -1993-. New aspects of the setting of glass-ionomer cements. J Dent Res72:481–483.

18.

Wilson AD, McLean JW -1988-. Glass-ionomer cement. Chicago: Quintessence Publishing Co.

Infrared Spectrometric Study of Acid-degradable Glasses

Abstract

Get full access to this article

References