Abstract
Five crystalline members of the hydroxyapatite (HAP; Ca5(PO4)3OH)–johnbaumite (JBM; Ca5(AsO4)3OH) series were crystallized at alkaline pH from aqueous solutions and used in dissolution experiments at 5, 25, 45, and 65 °C. Equilibrium was established within three months. Dissolution was slightly incongruent, particularly at the high-P end of the series. For the first time, the Gibbs free energy of formation ΔGf0, enthalpy of formation ΔHf0, entropy of formation Sf0, and specific heat of formation Cpf0 were determined for HAP–JBM solid solution series. Based on the dissolution reaction, Ca5(AsO4)m(PO4)3−mOH = 5Ca2+(aq) + mAsO43−(aq) + (3 − m)PO43−(aq) + OH−(aq), their solubility product Ksp,298.15 was determined. Substitution of arsenic (As) for phosphorus (P) in the structure of apatite resulted in a linear increase in the value of Ksp: from HAP logKsp,298.15 = −57.90 ± 1.57 to JBM logKsp,298.15 = −39.22 ± 0.56. The temperature dependence of dissolution in this solid solution series is very specific; in the temperature range of 5 °C to 65 °C, the enthalpy of dissolution ΔHr varied around 0. For HAP, the dissolution reaction at 5 °C and 25 °C was endothermic, which transitioned at around 40 °C and became exothermic at 45 °C and 65 °C.
Highlights
In the general chemical formula of minerals belonging to the apatite group A5 (XO4 )3 Z, position A represents cations (Ca, Ba, Ce, K, Na, Pb, Sr, and Y), atom X includes P, As, or V and occasionallyS or Si
The synthesis resulted in the precipitation of very fine, white, and crystalline powders
A small difference in particle size along the johnbaumite–hydroxyapatite (JBM–HAP) solid solution series was observed; the number of small particles decreased with decreasing P content in the structure
Summary
S or Si. In position Z, several anionic substitutions are possible, mostly F, Cl, Br, I, OH, O, or H2 O. Partial substitution of CO3 2− in both anionic positions has been commonly observed [1]. Low solubility, high durability, and the accommodation of a wide range of substitutions allow for the application of various apatites to remediation technologies involving immobilization of toxic elements such as Cd, Cu, Pb, U, Ni, Zn, I, Br, or As from polluted water, soil, and waste [2,3,4]. Ca5 (PO4 ) OH (HAP), is the primary component of bones and teeth. It is used, among others, as luminophosphor and in the production of phosphate-based fertilizers. Ionic substitution for Ca2+ , PO4 3− , and OH− in hydroxyapatite (HAP) is Minerals 2018, 8, 281; doi:10.3390/min8070281 www.mdpi.com/journal/minerals
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