长方体钻石之谜：生长区内光学中心反向分布的原因

IF 1.1 4区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Journal of Geosciences Pub Date : 2020-12-03 DOI:10.3190/jgeosci.301

E. Vasilev, D. Zedgenizov, I. Klepikov

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引用次数: 2

摘要

在目前的工作中，研究了具有黄色核和微色或无色边缘的钻石。已经确定了光谱特征不同的三组晶体。在第一类晶体中，颜色的不均一性是由于氮浓度的变化，氮以最简单的低温氮С中心存在。第一组吸收光谱分别在С和С+中心的1344和1332 cm-1波数处显示出峰值。第二组在色区也以C中心的形式显示出较高的氮浓度。但氮的浓度以高温形式存在А-centers，且总氮含量在晶体外围较高。该基团的FTIR吸收光谱显示1344和1332 cm-1峰。第三族晶体不含C中心。在FTIR吸收光谱中观察到1332 cm-1和A中心带。在第三族有色区的光致发光光谱中，发现了S1和S2波段以及最简单含镍中心的883和885 nm的双线线。在787 nm激发下，在第三族的光致发光光谱中记录了先前未观测到的在799.5、819.6、869.5和930 nm线处具有零声线的体系。据此提出，这种发光是由于含镍中心。在第三组晶体中，Ni似乎稳定了C+中心，因此晶体区域的颜色与Ni杂质分布一致。每一组的晶体都有不同的来源:第一组来自Yubileinaya管道，第二组来自北雅库特的砂矿，原始来源未知，第三组来自乌拉利亚矿床。

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The enigma of cuboid diamonds: the causes of inverse distribution of optical centers within the growth zones

In the present work, diamonds with yellow cores and a slightly colored or colorless rims have been studied. Three groups of crystals that differ in spectroscopic features have been identified. In the crystals of the first group, the heterogeneity in color is due to the variation in nitrogen concentration, which is present as the simplest low-temperature nitrogen С center. Absorption spectra of the first group display peaks at wavenumbers 1344 and 1332 cm–1 of С and С+ centers, respectively. The second group also exhibits higher nitrogen concentrations in the form of C centers in the colored zone. However, the concentration of nitrogen in the form of high temperature А-centers, and the total nitrogen content is higher at the periphery of crystals. The FTIR absorption spectra of this group display both 1344 and 1332 cm–1 peaks. Crystals of the third group do not contain C centers. The 1332 cm–1 and the A center bands are observed in the FTIR absorption spectra. In the photoluminescence spectra of the colored zone of the third group, the bands S1 and S2 have been found and the doublet lines 883 and 885 nm of the simplest Ni-containing centers. Previously unobserved systems with zerophonon lines at 799.5, 819.6, 869.5 and 930 nm lines have been registered in the photoluminescence spectra of the third group under 787 nm excitation. It is hereby proposed that this luminescence is due to Ni-containing centers. In the third group of crystals, Ni seems to stabilize C+ centers and hence the coloring of crystal zones is consistent with Ni impurity distribution. Crystals of each group have distinct sources: the first group is from Yubileinaya pipe, the second from the placers of North Yakutia with unknown primary sources and the third from the Uralian deposits.

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来源期刊

Journal of Geosciences GEOSCIENCES, MULTIDISCIPLINARY-MINERALOGY

CiteScore

2.30

自引率

7.10%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Geosciences is an international peer-reviewed journal published by the Czech Geological Society with support from the Czech Geological Survey. It accepts high-quality original research or review papers dealing with all aspects of the nature and origin of igneous and metamorphic rocks. The Journal focuses, mainly but not exclusively, on: -Process-oriented regional studies of igneous and metamorphic complexes- Research in structural geology and tectonics- Igneous and metamorphic petrology- Mineral chemistry and mineralogy- Major- and trace-element geochemistry, isotope geochemistry- Dating igneous activity and metamorphic events- Experimental petrology and mineralogy- Theoretical models of igneous and metamorphic processes- Mineralizing processes and mineral deposits. All the papers are written in English, even though they may be accompanied by an additional Czech abstract. Each contribution is a subject to peer review by at least two independent reviewers, typically at least one from abroad. The Journal appears 2 to 4 times a year. Formally it is divided in annual volumes, each of them including 4 issues.