近期市场出现的铬碧玺宝石学性质及谱学特征

Gemmological and Spectroscopic Characteristics of Chrome Tourmaline Appeared on the Market Recently

  • 摘要: 近期,市场上出现一种翠绿色碧玺,商家称之为铬碧玺,常切割成戒面出售,价格高于其它绿色碧玺。为了探究铬碧玺与普通绿色碧玺的差别,对从市场上收集到的铬碧玺以及普通绿色碧玺样品进行了折射率、密度等测试并观察其在查尔斯滤色镜下反应。采用傅里叶变换红外光谱仪(FTIR)、紫外-可见分光光度计(UV-Vis)以及X射线荧光光谱仪对样品进行测试。结果表明,铬碧玺的折射率为1.618~1.638,双折率为0.018~0.020,相对密度为3.05,查尔斯滤色镜下不变红,其宝石学性质与普通绿色碧玺相近。红外光谱测试结果表明,铬碧玺与普通碧玺在分子结构上并无明显差别,而紫外-可见吸收光谱以及X射线荧光光谱测试结果表明,铬碧玺中存在一定量的Cr元素,且在可见光波段中表现典型的Cr元素的吸收光谱,该特征与普通绿色碧玺明显不同,可以作为鉴别铬碧玺与普通绿色碧玺的诊断性特征。

     

    Abstract: According to the results of conventional tests, the refractive index of chrome tourmaline samples is ranged from 1.618 to 1.638, and the birefringence is 0. 018 to 0. 020 and the specific gravity is 3. 05. Under the Chelsea colour filter, chrome tourmaline samples do not show red colour, as well as normal green tourmaline samples. All samples present glassy luster, with flawless interior.
    Consistent with the standard spectrum of tourmaline, all samples have absorption peaks at 850-700 cm-1 that attribute to antisymmetric stretching vibration of Si-O-Si in the structure of tourmaline. Peaks at 1 150-980 cm-1 attribute to vibration of 0-Si-O and peak at 1 333 cm-1 attributes to vibration of (BO3)3-. Peaks at 630-500 cm-1 attribute to vibration of Si-0.M-0 and (BO3)3-. Peaks at 3 900-3 000 cm-1, got by transmission method, attribute to the vibration of (OH)-. The molecular structure of chrome tourmaline has no difference with normal green tourmaline according to the infrared spectrum.
    UV-Vis spectrophotometer analysis of chrome tourmaline samples presents two strong absorption bands around 400-470 nm and 570-630 nm, and an absorption peak at 680 nm.According to the previous research of UV-Vis spectrophotometer analysis of colour-causing Cr3+, the spectrum would be attributed to Cr3+. Unlikely, the normal green tourmaline samples show quite different spectrum, which has a weak absorption peak at 500 nm and a band around 670-770 nm. This analysis reveals that the chrome tourmalines is caused by Cr3+, which is different from normal green tourmalines. Further more, colour parameters of samples, including D-wavelength, purity, and CIE coordinate system(L*, a*, b*), do not have significance for the identification of chrome tourmaline.
    The results of energy dispersive X-ray fluorescence spectra of chrome tourmaline samples show the existence of chromophore as Cr and V, besides of ordinary component elements such as Ca, Mn and Fe, while the normal green tourmaline samples lack Cr and V.
    The results of researches suggest that the colour of chrome tourmalines from jewelry market is indeed caused by Cr3+, which can be used to distinguish from normal green tourmalines by UV-Vis spectrum and X-ray fluorescence spectrum.

     

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