光谱学与光谱分析 |
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Study on the Vibrational Spectra Characterization of Synthetic Jadeite Jade Made by General Electric Company |
CAO Shu-min1,3,QI Li-jian2,GUO Qing-hong3,4,ZHONG Zeng-qiu1,QIU Zhi-li5,LI Zhi-gang3 |
1. Faculty of Earth Science of China University of Geosciences,Wuhan 430074, China 2. Jewelry College of Tongji University(In Preparation), Shanghai 200092, China 3. Guangdong Provincial Gem & Precious Metal Testing Centre, Guangzhou 510080, China 4. Center for Earth Environment & Resources,Sun Yat-sen University, Guangzhou 510275, China 5. Department of Earth Science,Sun Yat-sen University, Guangzhou 510275, China |
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Abstract The object of the present study is the synthetic jadeite jade produced by American General Electric Corporation. Fourier transform infrared spectroscopy(FTIR) and Laser Raman spectroscopy were used to test its spectral properties in order to examine the feature of this kind of synthetic jadeite jade by vibrational spectroscopy and to figure out the mark for discriminate synthetic jadeite jade from natural jadeite jade. The study shows that GE synthetic jadeite jade is identical with natural jadeite jade in the main on fingerprint region in FTIR; There are clearly differences in the 2 000 -4 000 cm-1 functional region in FTIR: a group of frequencies at 3 375,3 471 and 3 614 cm-1 indicate vibration absorption of O—H. GE synthetic jadeite jade has proven consistent with natural jadeite jade in the laser Raman spectra by a group of sharp scattering peaks at 376,700,989 and 1 039 cm-1. In addition these scattering peaks show an intact crystal shape. The FTIR peaks and Raman spectral peaks shift to higher frequencies showing GE synthetic jadeite jade lacking isomorphism of heavy positive ions.
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Received: 2007-06-06
Accepted: 2007-09-08
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Corresponding Authors:
CAO Shu-min
E-mail: caoshumin@vip.sina.com
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[1] GUO Ying, XIONG Ning, SONG Gong-bao, et al(郭 颖, 熊 宁, 宋功保, 等). Journal of Southwest China Institute of Technology(西南工学院学报),2000,15(2): 46. [2] ZHAO Ting-he, CUI Shuo-jing, YAN Xue-wei(赵廷河, 崔硕景, 阎学伟). Acta Phystco-Chimica Sinica(物理化学学报),1994,10(7): 604. [3] ZHU Cheng-ming, JIN Zhi-sheng, CAI En-zhao, et al(朱成明, 金志升, 蔡恩照, 等). Acta Mineralogica Sinica(矿物学报),1997,17(3): 245. [4] WU Shi-xue, MA Xian-feng, YAN Xue-wei, et al(武士学, 马贤峰, 严学伟, 等). Journal of Synthetic Crystals(人工晶体学报),1988,17(Z1): 317. [5] MA Xian-feng, YAN Xue-wei(马贤锋,阎学伟). Journal of Inorganic Materials(无机材料学报),1996,11(4): 591. [6] CUI Shuo-jing, ZHAO Ting-he, YAN Xue-wei, et al(崔硕景, 赵廷河, 阎学伟, 等). Journal of High Pressure Physics(高压物理学报),1994,8(2): 99. [7] ZHU Cheng-ming, JIN Zhi-sheng, CAI En-zhao, et al(朱成明, 金志升, 蔡恩照,等). Acta Mineralogica Sinica(矿物学报),1997,17(3): 245. [8] YAN Xue-wei, MA Xian-feng, NI Jia-zan, et al(阎学伟, 马贤锋, 倪加缵, 等),Chinese Journal of High Pressure Physics(高压物理学报),1987,1(1):76. [9] WEI Ran, ZHANG Bei-li, SHEN Cai-qing(魏 然, 张蓓莉, 沈才卿). Journal of Gems & Gemology(宝石和宝石学杂志),2004,6(2): 7. [10] MA Ting-ting, LIAO Zong-ting(马婷婷, 廖宗廷). Shanghai Geology(上海地质),1998,(2): 43. [11] AO Yan, CHEN Jin(奥 岩, 陈 进). Jewellery Science and Jechnology(珠宝科技),1997,9(4): 37. [12] LIU Yan, DENG Jun, WANG Li-hua(刘 琰, 邓 军, 王丽华). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(3): 577. [13] QI Li-jian, YUAN Xin-qiang, CAO Shu-min(亓利剑, 袁心强, 曹姝旻). Journal of Gems & Gemmology(宝石和宝石学杂志),2005,7(4): 21. [14] ZU En-dong, CHEN Da-peng, ZHANG Peng-xiang(祖恩东, 陈大鹏, 张鹏翔). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2003,23(1): 64. [15] CAO Shu-min, QI Li-jian, GUO Qing-hong, et al(曹姝旻, 亓利剑, 郭清宏, 等). Journal of Gems & Gemmology(宝石和宝石学杂志),2006,8(1): 1. [16] YAN Yan-lu, ZHAO Long-lian, LI Jun-hui, et al(严衍禄, 赵龙莲, 李军会, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2000,20(6): 777. [17] ZHANG Bei-li, GAO Yan(张蓓莉, 高 岩). Journal of Gems & Gemmology(宝石和宝石学杂志),1999,1(2): 25. [18] LIU Shi-min(刘世敏). Rock and Mineral Analysis(岩矿测试 ),2006,25(1): 68. [19] LU Bao-qi, XIA Yi-ben, QI Li-jian, et al(卢保奇, 夏义本, 亓利剑, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2005,25(11): 1824. [20] QI Li-jian, Pei Jing-cheng(亓利剑, 裴景成). Journal of Gems&Gemmology(宝石和宝石学杂志),1999,(1): 1. [21] WANG Bai-song, TU Jing(王柏松, 屠 荆). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2000,20(1): 40. [22] CHEN Bing-hui, QIU Zhi-li, WANG Min, et al(陈炳辉, 丘志力, 王 敏, 等). Acta Mineralogica Sinica(矿物学报),2001,21(3): 525. [23] CHEN Mei-hua(陈美华). Earth Science-Journal of China University of Geosciences(地球科学-中国地质大学学报),1998,23(5): 528. [24] PENG Ming-sheng, Mao H K, LI Di-en(彭明生, Mao H K, 李迪恩). Spectroscopy and Spectral Analysis(光谱学与光谱分析),1991,11(5): 16. |
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