独居石
离子半径
氟磷灰石
标准生成焓
焓
稀土
矿物
磷灰石
化学
氧化物
氟化物
三元运算
热力学
无机化学
矿物学
物理化学
地球化学
地质学
离子
有机化学
计算机科学
程序设计语言
锆石
物理
作者
Radha Shivaramaiah,Andrzej Anderko,Richard E. Riman,Alexandra Navrotsky
出处
期刊:American Mineralogist
[Mineralogical Society of America]
日期:2016-05-01
卷期号:101 (5): 1129-1134
被引量:27
摘要
Bastnaesite, [RE-CO3-OH/F] (RE = rare earth) is one of the major sources of rare earth elements found in commercial deposits at Mountain Pass, California, Bayan Obo, China, and elsewhere. Synthetic forms of bastnaesite have been explored for applications including optical devices and phosphors. Determination of thermodynamic properties of these phases is critical for understanding their origin, mining, and processing. We report the first experimental determination of formation enthalpies of several OH and F bastnaesites based on high-temperature oxide melt solution calorimetry of well-characterized synthetic samples. The formation enthalpies from binary oxides and fluorides for all the bastnaesite samples are highly exothermic, consistent with their stability in the garnet zone of the Earth's crust. Fluoride bastnaesite, which is more abundant in nature than its hydroxide counterpart, is thermodynamically more stable. For both OH and F bastnaesite, the enthalpy of formation becomes more negative with increasing ionic radius of the RE3+ cation. This periodic trend is also observed among rare earth phosphates and several other rare earth ternary oxides. For a given RE, the formation enthalpies from binary oxides are more negative for orthophosphates than for bastnaesites, supporting the argument that monazite could have formed by reaction of bastnaesite and apatite at high temperature. The difference in formation enthalpy of monazite and bastnaesite provides insight into energetics of such reactions along the rare earth series.
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