|
|
|
|
|
|
The Gemological, Mineralogical, and Spectral Characteristics of Indian Longdan Stone |
ZHOU Wu-bang1, QIN Dong-mei2, WANG Hao-tian1, CHEN Tao1, WANG Chao-wen1* |
1. Gemmological Institute,China University of Geosciences (Wuhan),Wuhan 430074,China
2. Art and Communication College,Wuhan University of Engineering Science,Wuhan 430200,China
|
|
|
Abstract Indian Longdan stone was introduced into China as a carving stone because of its similar colors and materials to Qingtian Longdan stone. However, the spectral, mineral compositional, and structural characteristics of Indian Longdan stone are still unclear. In this paper, the gemmological characteristics, color genesis and spectral characteristics of a representative sample were studied by polarizing microscopy, X-ray Diffractometer (XRD), Scanning Electron Microscope (SEM), Electron Probe Micro Analyzer (EPMA) and Fourier Infrared Spectrometer (FTIR). Indian Longdan stone is characterized by “white meat and red heart”. The polarizing microscope shows that the illite is a cryptocrystalline lepidoblastic texture. Obvious red-brown spotted materials are aggregating in the “red heart” area, presenting as dense to loose from the central red area to the edge yellow-green area, consistent with the color change. XRD results show that the light yellow-green “white meat” and “red heart” diffraction patterns are the same, showing three strong diffraction peaks at 10.00,4.99 and 3.33 Å. Clear peaks can be observed at 2.86,2.99,3.20,3.49 and 3.73 Å and no other mineral phasecan be detected, indicating that the sample is pure 2M1 type illite. The full width at half maximum of XRD at 10.00 Å peak is 0.092°Δ two theta, indicating that the order and crystallinity of illite are well. EPMA further confirms that the Indian Longdan stone is mainly illite, with an average cation content of 0.824 p. u. f. and a structural iron content of 0.05%~0.08%. SEM backscattering composition images show that the red-brown patchy material has obvious bright contrast but generally shows similar morphology of illite. The energy spectrum analyses show that the average content of iron in this area is 0.48% wt, which is one order of magnitude higher than the content of structural iron in illite, indicating that the red-brown patchy iron-bearing material may be the chromogenic material of Indian Longdan stone. SEM observation reveals KCl crystals with cubic morphology, indicating that the illite may be directly crystallized in K-rich fluid. The results of FTIR show that the samples have an OH stretching vibration peak at 3 630 cm-1 and an Al—O vibration peak in tetrahedron at 830 cm-1. The absorption peak at 756 cm-1 is related to the substitution of Al in tetrahedral coordination instead of Si, which is characteristic of Si—O—Al vibration in the tetrahedron. The absorption peaks of OH stretching vibration near 3 625 cm-1 and at 825 and 750 cm-1 double fingerprints are the characteristic infrared absorption peaks of illite minerals, which confirms that the main mineral of Indian Longdan stone is illite. The study of Indian Longdan stone enriches the understanding of the gemmological and spectral characteristics of carved stone material, and the infrared spectral characteristics can be used as the identification basis for rapid, nondestructive testing of carved stone samples.
|
Received: 2022-03-22
Accepted: 2022-06-06
|
|
Corresponding Authors:
WANG Chao-wen
E-mail: c.w.wang@cug.edu.cn
|
|
[1] ZHU Xuan-min(朱选民). Journal of Gems and Gemmology (宝石和宝石学杂志),2010,(4): 17.
[2] ZENG Guang-ce,ZHU Yun-hai,YE De-long(曾广策,朱云海,叶德隆). Crystal Optics and Optical Mineralogy(晶体光学与光性矿物学). Wuhan: China University of Geosciences Press(武汉:中国地质大学出版社),2006.
[3] Kǜbler B. Les argiles,indicateurs de mé tamorphisme. Rev. Inst. Franc. Pé tro. 1964,19: 1093.
[4] Ji J,Chen J,Lu H. Clay Minerals,1999,34(4): 525.
[5] CHEN Tao(陈 涛). Study on Microstructure of Illite(伊利石的微结构特征研究). Beijing: Science Press(北京:科学出版社),2012.
[6] CHEN Li,ZHANG Li-fei,WANG He-jin,et al(陈 莉,张立飞,王河锦,等). Chinese Science Bulletin(科学通报),2004,(23): 2449.
[7] ZHU Xuan-min(朱选民). Conservation and Utilization of Mineral Resources(矿产保护与利用),2010,(5): 21.
[8] ZHU Hui-juan,ZHAO Xin-fen(朱惠娟,赵新奋). Multipurpose Utilization of Mineral Resources(矿产综合利用),2000,(6): 35.
[9] PENG Wen-shi,LIU Gao-kui(彭文世,刘高魁). Infrared Spectrum Atlas of Minerals(矿物红外光谱图集). Beijing: Science Press(北京:科学出版社),1982.
[10] ZHAO Xing-yuan,ZHANG You-yu(赵杏援,张有喻). Clay Minerals and Analysis of Clay Minerals(粘土矿物和粘土矿物分析). Beijing: China Ocean Press(北京:海洋出版社),1990. 209.
[11] LIU Wen-xin,TANG Hong-xiao(刘文新,汤鸿霄). Journal of Basic Science and Engineering(应用基础与工程科学学报),2001,(Z1): 164.
[12] ZHU Xuan-min(朱选民). Acta Petrologica et Mineralogica(岩石矿物学杂志),2003,22(1): 65.
|
[1] |
YU Lian-gang1, ZHENG Jin-yu2. Study on Mineral Composition and Spectroscopy Characteristics of
“African Dulong Jade”[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1676-1683. |
[2] |
CAO Qin-yuan1, SHI Miao2, 3, 4*, MA Shi-yu2. Spectral Characteristics and Analysis of Main and Trace Elements of Scheelite From Xuebaoding[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1689-1696. |
[3] |
ZHANG Juan1, LI Ke-xin2, QIN Dong-mei1, BAO De-qing1, 2, WANG Chao-wen2*. Spectroscopic Characteristics and Color Genesis of Yellowish-Green
Montebrasite[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(03): 777-783. |
[4] |
HE Yan1, TAO Ran1, YANG Ming-xing1, 2*. The Spectral and Technology Studies of Faience Beads Unearthed in Hubei Province During Warring States Period[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3700-3709. |
[5] |
TAO Long-feng1, 2, LIU Chang-jiang2, LIU Shu-hong3, SHI Miao2, HAN Xiu-li1*. Preparation and Spectral Characteristics of Mn2+ Doped Nephrite Tailings Glass[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2710-2714. |
[6] |
XU Ya-fen1, LIU Xian-yu1*, CHEN Quan-li2, XU Chang3. Study on Mineral Composition and Spectral Characteristics of “Middle East Turquoise”[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2862-2867. |
[7] |
YU Lian-gang1, LIU Xian-yu2*, CHEN Quan-li3. Gemstone Mineralogical and Spectroscopic Characteristics of
Quartzose Jade (“Mianlv Yu”)[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2543-2549. |
[8] |
LI Ming1, HONG Han-lie2. Gemological and Spectrographic Characteristics of Light-Green Tourmaline of Afghanistan[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2195-2201. |
[9] |
FAN Chun-hui1, 2, YUAN Wen-jing1, XIN Yi-bei1, GUO Chong1, LAN Meng-xin1, JIANG Zhi-yan1. Spectral Characteristics of Dissolved Organic Matter (DOM) in Reclaimed Water Used for Agricultural Irrigation in Water-Deficient Area for the Dual Carbon Targets[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(05): 1465-1470. |
[10] |
FU Wan-lu1, 2, LU Hao3*, CHAI Jun4, SUN Zuo-yu1. Spectroscopic Characteristics of Longxi Nephrite From Sichuan and Its Color Genesis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(05): 1408-1412. |
[11] |
ZHAO An-di1, 3, CHEN Quan-li1, 2, 3*, ZHENG Xiao-hua2, LI Xuan1, 3, WU Yan-han1, 3, BAO Pei-jin1, 3. Study on Spectroscopic Characteristics of Turquoise Treated With
Phosphate and Porcelain[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 1192-1198. |
[12] |
MAO Xiao-tian1, CHEN Chang2, YIN Zuo-wei1*, WANG Zi-min1. Spectra Characterization of Cr-Grossular (Tsavorite) With “Frogspawn” Color Zoning From Canada[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(02): 520-525. |
[13] |
BAO Pei-jin1, CHEN Quan-li1, 2*, WU Yan-han1, LI Xuan1, ZHAO An-di1. Spectroscopy Characteristics of Emerald From Swat Valley, Pakistan[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 213-219. |
[14] |
HE Yan1, SU Yue1, YANG Ming-xing1, 2*. Study on Spectroscopy and Locality Characteristics of the Nephrites in Yutian, Xinjiang[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(12): 3851-3857. |
[15] |
CAO Su-qiao1, DAI Hui1*, WANG Chao-wen2, YU Lu1, ZUO Rui1, WANG Feng1, GUO Lian-qiao1. Gemological and Spectral Characteristics of Emeralds From Swat Valley, Pakistan[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(11): 3533-3540. |
|
|
|
|