Compressibility and thermal expansion of magnesium phosphates

IF 1.8 3区地球科学 Q2 MINERALOGY European Journal of Mineralogy Pub Date : 2024-05-17 DOI:10.5194/ejm-36-417-2024

Catherine Leyx, Peter Schmid-Beurmann, Fabrice Brunet, Christian Chopin, Christian Lathe

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Abstract

Abstract. The ambient-temperature compressibility and room-pressure thermal expansion of two Mg3(PO4)2 polymorphs (farringtonite = Mg3(PO4)2-I, with 5- and 6-fold coordinated Mg, and chopinite = “Mg-sarcopside” = [6]Mg3(PO4)2-II), three Mg2PO4OH polymorphs (althausite, hydroxylwagnerite and ε-Mg2PO4OH, all with [5]Mg and [6]Mg) and phosphoellenbergerite ([6]Mg) were measured on synthetic powders using a synchrotron-based multi-anvil apparatus to 5.5 GPa and a laboratory high-temperature diffractometer, with whole-pattern fitting procedures. Bulk moduli range from 64.5 GPa for althausite to 88.4 GPa for hydroxylwagnerite, the high-pressure Mg2PO4OH polymorph. Chopinite, based on an olivine structure with ordered octahedral vacancies (K0 = 81.6 GPa), and phosphoellenbergerite, composed of chains of face-sharing octahedra (K0 = 86.4 GPa), are distinctly more compressible than their homeotypical silicate (127 and 133 GPa, respectively). The compressibility anisotropy is the highest for chopinite and the lowest for phosphoellenbergerite. First-order parameters of quadratic thermal expansions range from v1 = 2.19×10-5 K−1 for ε-Mg2PO4OH to v1 = 3.58×10-5 K−1 for althausite. Phosphates have higher thermal-expansion coefficients than the homeotypical silicates. Thermal anisotropy is the highest for farringtonite and the lowest for hydroxylwagnerite and chopinite. These results set the stage for a thermodynamic handling of phase-equilibrium data obtained up to 3 GPa and 1000 °C in the MgO–P2O5–H2O and MgO–Al2O3–P2O5–H2O systems.

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磷化镁的压缩性和热膨胀性

摘要。两种 Mg3(PO4)2 多晶体（farringtonite = Mg3(PO4)2-I，具有 5 倍和 6 倍配位镁；chopinite = "Mg-sarcopside" = [6]Mg3(PO4)2-II) 的环境温度可压缩性和室压热膨胀性、在合成粉末上使用基于同步加速器的多安维仪器测量了三种 Mg2PO4OH 多晶体（褐铁矿、羟基瓦格纳石和ε-Mg2PO4OH，均含有 [5]Mg 和 [6]Mg）和磷光体（[6]Mg），测量值达到 5.5 GPa 的合成粉末和实验室高温衍射仪进行了测量，并采用了整体图案拟合程序。块状模量范围从赤铁矿的 64.5 GPa 到羟基瓦格纳石（高压 Mg2PO4OH 多晶体）的 88.4 GPa。以具有有序八面体空位（K0 = 81.6 GPa）的橄榄石结构为基础的 Chopinite 和由面共享八面体链（K0 = 86.4 GPa）组成的磷光体，其可压缩性明显高于其原型硅酸盐（分别为 127 和 133 GPa）。可压缩性各向异性在筷子石中最高，在磷光体中最低。二次热膨胀的一阶参数范围从 ε-Mg2PO4OH 的 v1 = 2.19×10-5 K-1 到赤铁矿的 v1 = 3.58×10-5 K-1。磷酸盐的热膨胀系数高于同型硅酸盐。法氏磷酸盐的热各向异性最高，羟基瓦格纳石和筷子石的热各向异性最低。这些结果为从热力学角度处理 MgO-P2O5-H2O 和 MgO-Al2O3-P2O5-H2O 系统中获得的高达 3 GPa 和 1000 ℃ 的相平衡数据奠定了基础。

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来源期刊

European Journal of Mineralogy 地学-矿物学

CiteScore

2.80

自引率

9.50%

发文量

审稿时长

6-12 weeks

期刊介绍： EJM was founded to reach a large audience on an international scale and also for achieving closer cooperation of European countries in the publication of scientific results. The founding societies have set themselves the task of publishing a journal of the highest standard open to all scientists performing mineralogical research in the widest sense of the term, all over the world. Contributions will therefore be published primarily in English. EJM publishes original papers, review articles and letters dealing with the mineralogical sciences s.l., primarily mineralogy, petrology, geochemistry, crystallography and ore deposits, but also biomineralogy, environmental, applied and technical mineralogy. Nevertheless, papers in any related field, including cultural heritage, will be considered.