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Study on Laser Raman Spectrum Characteristics of Jadeite From Common Origins |
MA Ping1, 2, Andy Hsitien Shen1*, LUO Heng1, ZHONG Yuan1 |
1. Gemmological Institute, China University of Geosciences (Wuhan), Wuhan 430074, China
2. Hubei Land Resources Vocational College,Wuhan 430090,China
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Abstract Myanmar is the main commercial jadeite origin, Guatemala,Russia also have jadeite output. The value of jadeite from different origins varies greatly, and jadeite from other origins is impersonated as Burmese jadeite to get higher prices. Urgently need to be a reliable method to determine the geographic origin, the study of jadeite origin is of great significance in gemology. At present, jadeite from the different origins is mainly discussed in terms of jadeite generation age, mineral assemblage and jadeite component content, In this paper, jadeite from Myanmar, Russia and Guatemala is taken as the research object, lack of quick and effective ways to identify places of origins. The laser Raman spectroscopy of jadeite samples from different origins shows that the minerals of Jadeite from Myanmar are jadeite, chlorite and tremolite. The minerals of Guatemalan jadeite are relatively complex, including jadeite, omphacite,chlorite,titanite, uranite. The minerals of Russian jadeite are jadeite, albite and omphacite. By comparing the Raman characteristics of jadeite minerals from different origins, it is found that typical jadeite spectral characteristics show at 1 037,988,697,372 and 201 cm-1. At 1 020,679,369 and 216 cm-1,it shows the characteristic Raman displacement peaks of chlorite, and there are obvious tremolite absorption peaks at 215,332, 394,680 and 1 073 cm-1. tremolite is a secondary mineral in jadeite. Jadeite minerals from Guatemala are superimposed with Raman peaks of 680 and 218 cm-1,which is the peak value of the omphacite feature, and also contain the Raman peaks of chlorite feature near 603,537 and 306 cm-1. The results indicate that jadeite minerals from Guatemala are mostly replaced by Fe, Mg and Ca elements, forming jadeite-chlorite solid solution minerals. Raman spectral peaks of chlorite are detected on the surface of jadeite minerals, at 603,537 and 306,and chlorite alteration occurs on the surface of jadeite minerals. Russian Raman peaks of jadeite are superimposed with albitite Raman peak, at 1 100,507,473 and 164 cm-1 . Jadeite minerals in Russia are commonly metasomatized by albite Gray-green reticulated veins are distributed on the surface, and Raman peaks of 1 025,669,366 and 219 cm-1 are shown.
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Received: 2021-10-12
Accepted: 2022-03-01
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Corresponding Authors:
Andy Hsitien Shen
E-mail: ahshen@foxmail.com
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[1] Tsujimori T, Harlow G E. Eur. J. Mineral., 2012,24(2):371.
[2] QI Min, XIANG Hua, ZHONG Zeng-qiu, et al(祁 敏, 向 华, 钟增球, 等). Earth Science—Journal of China University of Geoscience(地球科学—中国地质大学学报), 2011,36(3):511.
[3] Pechar F, Rykl D. Can Mineral, 1983, 21(4): 689.
[4] LIN Chen-lu(林晨露). Master Dissertation(硕士论文). China University of Geosciences[中国地质大学(北京)],2020.
[5] ZHAO Ming-kai(赵明开). Yunnan Geology(云南地质), 2002, 21(2): 159.
[6] LIU Xue-liang, FAN Jian-liang, GUO Shou-guo(刘学良, 范建良, 郭守国). Laser & Optoelectronics Progress(激光与光电子学进展),2011, (9): 093002.
[7] Farmer V C. Infrared Spectroscopy of Mineral(矿物的红外光谱). Translated by YING Yu-pu, WANG Shou-song, LI Chun-geng, et al(应育浦, 汪寿松, 李春庚, 等译). Beijing: Science Press(北京: 科学出版社), 1982. 304.
[8] REN Qian-qian, YUAN Yi-chai(任芊芊, 袁一钗). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2021, 41(7): 2263.
[9] CHEN Yu-han(陈宇涵). Master Dissertation(硕士论文). Guilin University of Technology(桂林理工大学),2019. |
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