Density of Compound Oxides.

KAMIGAITO Osami

doi:10.2109/jcersj.108.1262_944

A method of predicting the density of compound oxides was given on the basis of the density of the single oxides which can be regarded to compose the compound oxide. A compound oxide is first expressed in the form of a combination of single oxides, such as 2MgO⋅SiO₂ for forsterite (Mg₂SiO₄), being applicable to any compound oxide. The density, D_a, of the mixture of single oxides whose composition is identical to that of the compound oxide, 2MgO and SiO₂, by way of example, is then calculated from the molar weight (W) and the density (d) of the component single oxides; D_a=(2W_MgO+W_SiO2)/{2(W_MgO/d_MgO)+(W_SiO2/d_SiO2)}. D_a is approximated to be the density of the compound, D_c. The deviation, (D_c-D_a)/D_a(=δ), was calculated for 88 popular silicates and non-silicate oxides. δ was found to be within ±0.1 for about 80% of the oxides examined. Furthermore, δ was found to be positively large for oxides with a higher density and negatively large for oxides with a lower density. The silicates having a negatively large δ have a tendency to exhibit a negative thermal expansion, and those with a positively large δ tend to have high hardness. The relationship of δ to D_c leads to the following approximations; D_c=D_a {1+0.33(D_a-3.1)} for silicates, and D_c=D_a {1+0.11(Da-5.3)} for non-silicate oxides. Both of these empirical expressions hold within an error of less than 10% for most oxides, though a more detailed examination with much more data will be necessary. The assumed density of 2.0 for Si (F, OH)₄ and Si(OH)₄ results in a good approximation for the densities of (F, OH)- and (OH)-containing silicates.

Density of Compound Oxides.

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