Mechanochemical synthesis and transformation of the polymorphic double carbonates fairchildite and buetschliite, (K2Ca(CO3)2): an in situ X-ray powder diffraction study†

RSC Mechanochemistry Pub Date : 2024-11-28 DOI:10.1039/D4MR00093E

Volker Kahlenberg, Doris E. Braun, Wolfgang Schmidt, Hang Liu, Sebastian Leiting and Claudia Weidenthaler

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Abstract

This study presents the mechanochemical synthesis of the two K₂Ca(CO₃)₂ polymorphs, fairchildite and buetschliite, from CaCO₃ and K₂CO₃ using a shaker mill. Unlike previous methods requiring high temperatures and prolonged heating, fairchildite, a high-temperature polymorph, is formed initially in all experiments, adhering to Ostwald's rule of stages. Notably, the transformation to the stable buetschliite phase can be achieved by varying milling parameters, particularly frequency and moisture content. The results suggest that pressure, rather than temperature, plays a significant role in this phase transition, with moisture further accelerating the transformation. These findings offer a new, efficient route for the synthesis of these polymorphs, highlighting the critical influence of milling conditions on the reaction pathway.

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多晶双碳酸盐（K2Ca(CO3)2）的机械化学合成与转化：原位x射线粉末衍射研究。

本文研究了以碳酸钙和K2CO3为原料，在摇床上机械化学合成了两种K2Ca(CO3)2多晶物fairchildite和buetschliite。与以往需要高温和长时间加热的方法不同，fairchildite是一种高温多晶体，在所有实验中都是最初形成的，遵循奥斯特瓦尔德阶段规则。值得注意的是，通过改变磨矿参数，特别是磨矿频率和含水率，可以实现向稳定辉石相的转变。结果表明，压力而不是温度在这一相变中起着重要作用，而湿度进一步加速了这一转变。这些发现为合成这些多晶体提供了一条新的、有效的途径，突出了铣削条件对反应途径的关键影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RSC Mechanochemistry

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