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| Mineralogical and Spectroscopic Characterisation of Multicoloured Pigments From Sanwei Moutain at Dunhuang |
| LI Lin-xiao1, TAN Yu-chen1*, XIAN Yi-heng1, TIE Fu-de1, 2, SUN Man-li1, AI Hao1, LIANG Yun1, SUN Feng1 |
1. School of Cultural Heritage, Northwest University, Xi'an 710127, China
2. National Museum of China, Beijing 100006, China
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Abstract An ancient mine site for extracting multicolored pigments was discovered at the Flame Gorge of the SanWei Mountain, Dunhuang, which holds academic value for researching the sources of ancient mineral pigments in northwestern China. To determine the mineral species and spectral characteristics of pigments discovered there, we employed polarized light microscopy, X-ray diffraction, Laser Raman spectroscopy, and X-ray fluorescence spectroscopy to analyzethe pigment production. The results indicate that the mineral pigments produced from SanWei Mountain are natural minerals, primarily Fe2O3 (average 66%) and SiO2, etc. Some of the samples are rich in silica-aluminum, and all of them have different degrees of loss-on-ignition. The main phases are hematite, goethite, and some jarosite. The gangue minerals include quartz, kaolinite, and clay minerals. The color phase of pigment minerals was further analyzed by Raman spectroscopy. The color phase of bright No.2 minerals was consistent with the main phase discussed above, namely jarosite and natrojarosite. All the reddish-brown samples except for No.4 contain α-Fe2O3, hematite, which causes the reddish-brown color. Sample No.4 contain sgoethiteand become sreddish-brown due to the presence of hematite, which is associated with yet is much stronger in color than hematite and, therefore, changes the color of sample No.4. In conclusion, the red mineral pigment produced at this ancient minesite is mainly hematite. The yellow mineral pigment is jarosite and natrojarosite. As an excellent pigment, jarosite is used in rock paintings and murals, but it has not been found in the frescoes studied in the Mogao Caves.This discovery has extended the dimension of yellow mineral pigments in northwestern China. It provides basic support for the subsequent pigment flow of the pigments produced in this mining and metallurgical site.
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Received: 2023-12-06
Accepted: 2024-05-27
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Corresponding Authors:
TAN Yu-chen
E-mail: yuchen_tan@nwu.edu.cn
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[1] Dunhuang City Chronicle Compilation Committee(敦煌市志编篡委员会). Dunhuang Chronicles(敦煌市志). Beijing:Xinhua Press(北京: 新华出版社), 1994. 156.
[2] WANG Jin-yu(王进玉). Dunhuangnology and History of Science & Technology(敦煌学和科技史). Lanzhou: Gansu Education Press(兰州: 甘肃教育出版社), 2011. 191.
[3] WANG Jin-yu(王进玉). Shanghai Journal of Traditional Chinese Medicine(上海中医药杂志), 1998,(12): 30.
[4] XU Yong(徐 勇). Journal of Dunhuang Studies(敦煌学辑刊),2006,(4): 80.
[5] LI Ya-dong(李亚东). A Century of Dunhuang Studies in China Cave Conservation(中国敦煌学百年文库石窟保护卷). Lanzhou: Gansu Culture Press(兰州: 甘肃文化出版社), 1999. 201.
[6] MEI Hua-lin, YU Hai-feng, LI Quan, et al(梅华林, 于海峰, 李 铨,等). Progress in Precambrian Research(前寒武纪研究进展), 1997,(4): 47.
[7] FENG Zhi-shuo, ZHANG Zhi-cheng, LI Jian-feng, et al(冯志硕, 张志诚, 李建锋,等). Acta Petrologica Sinica(岩石学报),2010, 26(2): 607.
[8] WANG Nan, WU Cai-lai, MA Chang-qian, et al(王 楠, 吴才来, 马昌前,等). Acta Geologica Sinica(地质学报), 2016, 90(10): 2681.
[9] Gansu Geology and Minerals Bureau(甘肃省地质矿产局). Gansu Regional Geological Journal(甘肃省区域地质志). Beijing:Geology Press(北京: 地质出版社), 1989. 7.
[10] ZHAO Yan, DIWU Chun-rong, ZHU Tao, et al(赵 燕, 第五春荣, 朱 涛,等). Acta Petrologica Sinica(岩石学报), 2015, 31(7): 1855.
[11] XIA Yin, et al(夏 寅, 等). Polarized Microscopic Analysis of Ancient Chinese Pigments(中国古代颜料偏光显微分析研究). Beijing:Science Press(北京: 科学出版社),2017. 24.
[12] De Faria D L A, Silva S V, De Oliveira M T. Journal of Raman Spectroscopy, 1997,28(11): 873.
[13] GONG Xiao-ye, YOU Jing-lin, WANG Jian, et al(龚晓晔, 尤静林, 王 建,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2018, 38(S1): 241.
[14] LI Zui-xiong(李最雄). Dunhuang Research(敦煌研究), 2004,(4): 11.
[15] YANG Jing, ZHENG De-wen, CHEN Wen, et al(杨 静, 郑德文, 陈 文,等). Journal of Geomechanics(地质力学学报), 2017, 23(2): 232.
[16] ZHANG Yun-xia, WANG Meng,GUO Zhao-qing, et al(张云霞, 王 蒙, 郭兆清, 等). The Journal of Light Scattering(光散射学报), 2016, 28(4): 317.
[17] Robert G Bednarik. Rock Art Science: The Scientific Study of Palaeoart. Bednarik Aryan Books International, 2007. 93.
[18] WU Rong-jian(吴荣鉴). Dunhuang Research(敦煌研究), 2003,(5): 44.
[19] WANG Jin-yu(王进玉). Dunhuang Research(敦煌研究), 1986,(4): 78.
[20] CHEN Qing, WANG Jun-hu, Sugishita Ryuichiro(陈 青,王军虎, 杉下龙一郎). Sciences of Conservation and Archaeology(文物保护与考古科学), 1996,(1): 9.
[21] ZHOU Guo-xin(周国信). Archaeology(考古), 1990,(5): 467.
[22] Cornell R M, Schwertmann U. Iron Oxides in the Laboratory: Preparation and Characterization. Wiley-VCH Verlag GmbH, 2000. 133.
[23] LIU Yu-quan(刘玉权). China Grottoes-AnxiYulin Grottoes(中国石窟·安西榆林窟). Beijing: Culture Relics Press(北京: 文物出版社), 2012. 216.
[24] WANG Jin-yu(王进玉). Sciences of Conservation and Archaeology(文物保护与考古科学), 2003, 15(3): 47.
[25] CUI Min(崔 敏). Identification and Apperciation to Cultural Relics(文物鉴定与鉴赏), 2023,(13): 114.
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