光谱学与光谱分析 |
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IR Spectrum Characteristics and Significance of Luodian Jade from Guizhou |
YANG Lin1,2, LIN Jin-hui1, WANG Lei2, WANG Bing2, DU Ying3* |
1. Chengdu University of Technology, Chengdu 610059, China 2. Ministry of Land and Resources, Guiyang Supervision Testing Center for Mineral Resources, Guiyang 550004, China 3. School of Chemistry and Materials Science, Guizhou Normal Univerity, Guiyang 550001, China |
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Abstract In the present paper we selected some typical samples from Luodian jade to perform FTIR test in order to study the vibration attribution of crystals structure. The results confirm that the main mineral composition of Luodian jade is tremolite. Not only has it been not reported in other IR study on natural nephrite that the absorption bands at wave numbers between 840 and 860 cm-1 caused by residual diopside exist in Luodian jade with the process of tremolite rock transformed to nephrite, but is also the biggest difference between the Luodian jade and other nephrite. The results reveal important mineralogy evidence of metamorphism of Luodian jade, and on the other hand, it also shows that there is a certain difference in the process of nephrite change between Luodian jade and other natural nephrite. Moreover, it further suggests that Luodian jade is a kind of new genetic nephrite ore.
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Received: 2012-12-20
Accepted: 2013-03-25
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Corresponding Authors:
DU Ying
E-mail: 346819266@qq.com
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[1] Fernandes S, Khan M, Cheudhary G. Journal of Gems and Gemmology(宝石和宝石学杂志), 2003, 5(2): 34. [2] QI Li-jian, YUANG Xin-qiang, CAO Shu-min(亓利剑, 袁心强, 曹姝旻). Journal of Gems and Gemmology(宝石和宝石学杂志), 2005, 7(4): 21. [3] YUAN Xin-qiang, QI Li-jian, ZHENG Nan(袁心强, 亓利剑, 郑 南). Journal of Gems and Gemmology(宝石和宝石学杂志), 2005, 7(4): 17. [4] GUO Li-he, HAN Jing-yi, LUO Hong-yu(郭立鹤, 韩景仪, 罗红宇). Acta Petrological et Mineralogical(岩石矿物学杂志), 2006, 25(4): 349. [5] Kloprogge J T, Visser D, Ruan H, et al. Journal of Materials Science Letters, 2001, 20: 1497. [6] Ishida K, Jenkins D M, Hawth F C. American Mineralogist, 2008, 93: 1112. [7] Strens R G J. Mineralogical Society Monograph 4, London, 1974. 305. [8] Ishida K, Frank C. Yumi A H. American Mineralogist, 2002, 87: 891. [9] Hawthorne F C, Della V G, Robert J L. American Mineralogist, 1996, 81: 782. [10] Della V G, Robert J L, Raudsepp M, et al. American Mineralogist, 1997, 82: 291. [11] Giancarl D V, Frank C. Hawthorne J L R, et al. Eur. J. Mineral, 2003, 15: 341. [12] Gottschalk M, Najorka J, Andrut M. Phys. Chem. Minerals, 1998, 25: 415. [13] Hawthorne F C, Della V G, Robert J L, et al. American Mineralogist, 1997, 82: 708. [14] Stefanm E, Matthtags O, Michaela N, et al. Eur. J. Mineral, 2000, 12: 273. [15] Andrut M, Gottschalk M, Melze, S, et al. Physics and Chemistry of Minerals, 2000, 27: 301. [16] YANG Lin,LIN Jin-hui,WANG Lei,et al(杨 林,林金辉,王 雷,等). Jouranl of Mineralogy and Petrology(矿物岩石),2012, 32(2):12. [17] Ishida K, Jenkins D M, Hawth F C. American Mineralogist, 2008, 93: 1112. [18] WANG Duo,XU Ze-bin,SUN Meng,et al(王 铎,徐泽彬,孙 猛,等). Infrared Technology(红外技术), 2009,31(12):698. |
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