论文信息 - Compression mechanisms in α‐quartz structures—SiO2 and GeO2

Compression mechanisms in α‐quartz structures—SiO2 and GeO2

Interatomic distances and angles have been measured at pressures to about 25 kbars for the α‐quartz forms of SiO2 and GeO2 using time‐of‐flight powder neutron diffraction. The data show that the compression of SiO2 results solely from a cooperative rotation or tilting of the SiO4 tetrahedra around their shared oxygen corners, with individual tetrahedra remaining relatively rigid. Conversely, the compression of GeO2 results almost solely from distortions of the individual tetrahedra resulting from changes in O‐Ge‐O angles with cooperative rotations contributing a negligible amount.

J. D. Jorgensen | J. Jorgensen

[1] D. Taylor,et al. The thermal expansion behaviour of the framework silicates , 1972, Mineralogical Magazine.

[2] R. Roy,et al. Studies of Silica‐Structure Phases: I, GaPO4, GaAsO4, and GaSbO4 , 1956 .

[3] M. Murthy. Thermal‐Expansion Properties of Vitreous and Crystalline Germania , 1962 .

[4] B. Dorner,et al. On the mechanism of the α-β phase transformation of quartz , 1974 .

[5] Daniel L. Decker,et al. High‐Pressure Equation of State for NaCl, KCl, and CsCl , 1971 .

[6] T. G. Worlton,et al. Multicomponent profile refinement of time-of-flight neutron diffraction data , 1976 .

[7] T. G. Worlton,et al. High-pressure neutron diffraction study of Si2N2O , 1977 .

[8] D. Mcwhan. Linear Compression of α‐Quartz to 150 kbar , 1967 .

[9] J. Carpenter. Extended detectors in neutron time-of-flight diffraction experiments , 1967 .

[10] G. S. Smith,et al. The crystal structure of quartz‐like GeO2 , 1964 .

[11] D. Cruickshank. 1077. The rôle of 3d-orbitals in π-bonds between (a) silicon, phosphorus, sulphur, or chlorine and (b) oxygen or nitrogen , 1961 .

[12] G. S. Smith. On the regularity of the tetrahedra in quartz , 1963 .