CRYSTAL-CHEMICAL OBSERVATIONS AND THE RELATION BETWEEN SODIUM AND WATER IN DIFFERENT BERYL VARIETIES

The Canadian Mineralogist Pub Date : 2022-07-01 DOI:10.1130/abs/2021am-366554

Rhiana E. Henry, L. Groat, R. Evans, J. Cempírek, R. Škoda

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Abstract

Beryl (Be3Al2Si6O18) is a well-known mineral, most famously in its vivid green form of emerald, but also as a range of other colors. Prominent varieties of beryl aside from emerald include aquamarine, red beryl, heliodor, goshenite, and morganite. There has not been a significant amount of research dedicated to comparing the crystal-chemical differences among the varieties of beryl except in determining chromophoric cations. While the H2O content within structural channels of emerald has been explored, and the H2O content of individual beryl specimens has been studied, there has not yet been a study comparing the H2O content systematically across beryl varieties. In this study we consider single-crystal X-ray diffraction data and electron probe microanalyses of 80 beryl specimens of six primary varieties, to compare and contrast their crystal chemistry. Beryl cation substitutions are dominantly coupled substitutions that require Na to enter a structural channel site. The results indicate that with increasing Na content beryl varieties diverge into two groups, characterized by substitutions at octahedral or tetrahedral sites, and that the dominant overall cation substitutions in each beryl variety tend to be different in more than just their chromophores. We find that the relation between Na and H2O content in beryl is consistent for beryl with significant Na content, but not among beryl with low Na content. Natural red beryl is found to be anhydrous, and heliodor has Na content too low to reliably determine H2O content from measured Na. We determined equations and recommendations to relate the Na and H2O content in emerald, aquamarine, goshenite, and morganite from a crystallographic perspective that is applicable to beryl chemistry measured by other means. This research will help guide future beryl studies in classifying beryl variety by chemistry and structure and allow the calculation of H2O content in a range of beryl varieties from easily measured Na content instead of requiring the use of expensive or destructive methods.

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不同绿柱石品种的晶体化学观察及钠和水的关系

绿柱石(Be3Al2Si6O18)是一种众所周知的矿物，最著名的是它的翠绿形式，但也有一系列其他颜色。除了祖母绿外，绿柱石的主要品种包括海蓝宝石、红绿柱石、日光绿柱石、歌绿柱石和钼矿石。除了确定显色阳离子外，还没有大量的研究致力于比较绿柱石品种之间的晶体化学差异。虽然对祖母绿结构通道内的H2O含量进行了探索，并对单个绿柱石标本的H2O含量进行了研究，但尚未有系统地比较不同绿柱石品种间的H2O含量的研究。本文对6个主要品种的80个绿柱石样品进行了单晶x射线衍射和电子探针显微分析，比较和对比了它们的晶体化学性质。绿柱基阳离子取代主要是偶联取代，需要Na进入结构通道位点。结果表明，随着Na含量的增加，绿柱石品种分为两类，其特征是在八面体或四面体位点上发生取代，并且每种绿柱石品种的主要阳离子取代不仅仅是在它们的发色团上不同。我们发现，在Na含量高的绿柱石中，Na与H2O的关系是一致的，而在Na含量低的绿柱石中，Na与H2O的关系则不一致。发现天然红绿柱石是无水的，而太阳石的Na含量太低，无法通过测量的Na可靠地确定H2O含量。我们从晶体学的角度确定了有关祖母绿、海蓝宝石、歌岭石和钼矿中Na和H2O含量的公式和建议，适用于其他方法测量的绿柱石化学。该研究将有助于指导未来的绿柱石研究，根据化学和结构对绿柱石品种进行分类，并允许从容易测量的Na含量计算一系列绿柱石品种中的H2O含量，而不需要使用昂贵或破坏性的方法。

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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The Canadian Mineralogist

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