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dc.contributor.authorCuesta, A-
dc.contributor.authorDe la Torre, AG-
dc.contributor.authorLosilla, ER-
dc.contributor.authorPeterson, VK-
dc.contributor.authorRejmak, P-
dc.contributor.authorAyuela, A-
dc.contributor.authorFrontera, C-
dc.contributor.authorAranda, MAG-
dc.identifier.citationCuesta, A., De la Torre, A. G., Losilla, E. R., Peterson, V. K., Rejmak, P., Ayuela, A., Frontera, C., & Aranda, M. A. G. (2013). Structure, atomistic simulations, and phase transition of stoichiometric yeelimite. Chemistry of Materials, 25 (9), 1680-1687. doi:10.1021/cm400129zen_AU
dc.description.abstractYeelimite, Ca-4[Al6O12]SO4, is outstanding as an aluminate sodalite, being the framework of these type of materials flexible and dependent on ion sizes and anion ordering/disordering. On the other hand, yeelimite is also important from an applied perspective as it is the most important phase in calcium sulfoaluminate cements. However, its crystal structure is not well studied. Here, we characterize the room temperature crystal structure of stoichiometric yeelimite through joint Rietveld refinement using neutron and Xray powder diffraction data coupled with chemical soft-constraints. Our structural study shows that yeelimite has a lower symmetry than that of the previously reported tetragonal system, which we establish to likely be the acentric orthorhombic space group Pcc2, with a root 2a x root 2a X a superstructure based on the cubic sodalite structure. Final unit cell values were a = 13.0356(7) angstrom, b = 13.0350(7) angstrom, and c = 9.1677(2) angstrom. We determine several structures using density functional theory calculations, with the lowest energy structure being Pcc2 in agreement with our experimental result. Yeelimite undergoes a reversible phase transition to a higher-symmetry phase which has been characterized to occur at 470 degrees C by thermodiffractometry. The higher-symmetry phase is likely cubic or pseudocubic possessing an incommensurate superstructure, as suggested by our theoretical calculations which show a phase transition from an orthorhombic to a tetragonal structure. Our theoretical study also predicts a pressure-induced phase transition to a cubic structure of space group 1 (4) under bar 3m. Finally, we show that our reported crystal structure of yeelimite enables better mineralogical phase analysis of commercial calcium sulfoaluminate cements, as shown by R-F values for this phase, 6.9% and 4.8% for the previously published orthorhombic structure and for the one reported in this study, respectively. © 2013, American Chemical Society.en_AU
dc.publisherAmerican Chemical Society.en_AU
dc.titleStructure, atomistic simulations, and phase transition of stoichiometric yeelimiteen_AU
dc.typeJournal Articleen_AU
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