Carbonate apatite is a material of the utmost importance as it represents the inorganic fraction of biological hard tissues in bones and teeth. Here we study the static and dynamic features of CO32- ion in the apatitic channel of carbonate apatite (A-type substitution), by applying both static and dynamic quantum mechanical calculations based on density functional methods with B3LYP-D* and PBE functionals. The static calculations reveal a number of almost energetically equivalent carbonate configurations in the channel, leading to cell parameters compatible with the P3Ì... space group assigned by the experimental X-ray structure determination. Ab initio isothermal-isobaric molecular dynamics simulations provide insights on the CO32- mobility, showing that at the temperature of the experimental structural determination the CO32- moiety undergoes a dynamic disorder, as the carbonate group is almost free to move within the apatitic channel enhancing its exchangeability with other anions. © 2013 American Chemical Society.
CO32- mobility in carbonate apatite as revealed by density functional modeling / Peccati, F.; Corno, M.; Delle Piane, M.; Ulian, G.; Ugliengo, P.; Valdre, G.. - In: JOURNAL OF PHYSICAL CHEMISTRY. C. - ISSN 1932-7447. - 118:2(2014), pp. 1364-1369. [10.1021/jp4108415]
CO32- mobility in carbonate apatite as revealed by density functional modeling
Delle Piane M.;
2014
Abstract
Carbonate apatite is a material of the utmost importance as it represents the inorganic fraction of biological hard tissues in bones and teeth. Here we study the static and dynamic features of CO32- ion in the apatitic channel of carbonate apatite (A-type substitution), by applying both static and dynamic quantum mechanical calculations based on density functional methods with B3LYP-D* and PBE functionals. The static calculations reveal a number of almost energetically equivalent carbonate configurations in the channel, leading to cell parameters compatible with the P3Ì... space group assigned by the experimental X-ray structure determination. Ab initio isothermal-isobaric molecular dynamics simulations provide insights on the CO32- mobility, showing that at the temperature of the experimental structural determination the CO32- moiety undergoes a dynamic disorder, as the carbonate group is almost free to move within the apatitic channel enhancing its exchangeability with other anions. © 2013 American Chemical Society.Pubblicazioni consigliate
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https://hdl.handle.net/11583/2977619