High-pressure behavior and structural transition of beryl-type johnkoivulaite, Cs(Be2B)Mg2Si6O18 [High-pressure behavior and structural transition of beryl-type johnkoivulaite, Cs(Be₂B)Mg₂Si₆O₁₈]
Articolo
Data di Pubblicazione:
2024
Citazione:
High-pressure behavior and structural transition of beryl-type johnkoivulaite, Cs(Be2B)Mg2Si6O18 [High-pressure behavior and structural transition of beryl-type johnkoivulaite, Cs(Be₂B)Mg₂Si₆O₁₈] / G. Diego Gatta, M. Ende, S. Miloš, N. Rotiroti, A.C. Palke, R. Miletich. - In: AMERICAN MINERALOGIST. - ISSN 0003-004X. - 109:1(2024), pp. 15-23. [10.2138/am-2022-8908]
Abstract:
The beryl-group mineral johnkoivulaite, Cs(Be2B)Mg2Si6O18, was compressed hydrostatically in a diamond-anvil cell up to 10.2 GPa. In situ Raman spectroscopy and X-ray crystallography revealed a P6/mcc-to-P3c1 (second-order) phase transition on isothermal compression at the critical transition pressure Pc = 4.13 ± 0.07 GPa. The elastic parameters determined for the volume elasticity of the two polymorphs correspond to a Birch-Murnaghan equation of state with K0 = 148 ± 2 GPa and K′ = 0 for P < Pc and K0 = 75.5 ± 0.9 GPa with K′ = 4 for P > Pc. The low-P polymorph shows anomalously linear compression behavior, as reported for several other beryl-derived framework structures. The high-P polymorph, which was found to follow a a′ = a·√3, c′ = c superstructure according to P3c1, is almost twice as compressible as its low-P form. This is unique for any beryl-derived structure and can be attributed to the high degree of freedom for atomic displacements in the superstructure. The reduced symmetry can also be understood as the effect of the driving mechanism of the transformation. The extra-framework Cs channel components counteract any lateral deformation of the channels parallel to [0001] within the microporous framework and, similar to pezzottaite, are responsible for maintaining the trigonal/hexagonal lattice metrics.
Tipologia IRIS:
01 - Articolo su periodico
Keywords:
Beryl-type structure; johnkoivulaite; high pressure; structural transition; second-order phase transition; superstructure; Microporous Materials: Crystal-chemistry; Properties; and Utilizations;
Elenco autori:
G. Diego Gatta, M. Ende, S. Miloš, N. Rotiroti, A.C. Palke, R. Miletich
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