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A Scientific Research of the Painted Potteries of the Yangshao Culture from the Miao-Di-Gou Site |
ZHAO Ling-wei1, 2, CHEN Hai-long3, ZHAO Hong-xia1, DONG Jun-qing1, LI Qing-hui1* |
1. Center of Sci-Tech Archaeology, Shanghai Instituteof Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, China
2. Institute of Optics and Fine Mechanics,University of Chinese Academy of Sciences, Beijing 100049, China
3. College of Optoelectronic Engineering, Shenzhen University, Shenzhen 518060, China |
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Abstract As a great invention in the Neolithic age, painted pottery culture changed the aesthetic way of ancient ancestors. And the famous Yangshao culture with its painted pottery’s beautiful shape, bright colors and rich ornamentation reveals the artistic features of the original and carries important social and cultural information in prehistoric times. With the accurate, nondestructive and micro damage characteristics of modern spectral analysis technology, it can provide more scientific support for the research on preservation of cultural relics. This paper makes a comprehensive analysis of the painted pottery bowls of Yangshao culture unearthed from Miao-di-gou site dated to the late Neolithic period in Shanxian county, Sanmenxia, Henan province with optical three-dimensional scanning, self-built multispectral imaging, X-ray fluorescence spectrometer (XRF) and laser Raman spectroscopy. The physical and chemical information of the painted pottery is obtained. The digital model of painted pottery bowls are constructed by three-dimensional scanning technique, and the geometric dimension of the samples is non-contacted measured and virtual restoration of digital images of samples are obtained. The similar regions of the chemical characteristics of the sample surface are distinguished from the gray image obtained by multispectral imaging. The chemical compositions and pigment phases of the painted pottery are determined by X-ray fluorescence spectrometer (XRF) and laser Raman spectroscopy. Based on the results of comprehensive research, a digital model of multi-source information of painted pottery relics is put forward, which provides basic scientific information for digital protection and display of such kind of cultural relics.
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Received: 2017-06-15
Accepted: 2017-11-26
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Corresponding Authors:
LI Qing-hui
E-mail: qinghuil@sina.com
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[1] The Institute of Archaeology CASS(中国社会科学院考古研究所). Chinese Archaeology·Neolithic(中国考古学·新石器时代卷). Beijing: Chinese Social Science Press(北京: 中国社会科学出版社), 2010. 206.
[2] The Institute of Archaeology CASS(中国社会科学院考古研究所). Miaodigou and Sanliqiao(庙底沟与三里桥). Beijing: Science Press(北京: 科学出版社),1959.
[3] HAN Jian-ye(韩建业). Archaeology and Cultural Relics(考古与文物),2013, (1): 28.
[4] HUA Nian(华 年). Journal of South China Normal University·Social Sciences Edition(华南师范大学学报·社会科学版), 2012, (3): 145.
[5] AN Zhi-min(安志敏). Archaeology(考古), 1961, (7): 385.
[6] MA Bao-guang, MA Zi-qiang(马宝光, 马自强). Cultural Relics of Central China(中原文物), 1988,(3): 33.
[7] WU Li(吴 力). Archaeology(考古), 1973, (5): 292.
[8] XIE Rui-ju, YE Wan-song(谢端琚,叶万松). Archaeology and Cultural Relics(考古与文物), 1998, (1): 50.
[9] ZENG Qi(曾 骐). Journal of Sun Yat-Sen University·Social Science Edition(中山大学学报·社会科学版), 1992, (4): 91.
[10] LI Xiang-sheng(李湘生). Cultural Relics of Central China(原文物), 1984, (1): 53.
[11] ZHANG Peng-cheng(张鹏程). Archaeology and Cultural Relics(考古与文物), 2014, (5): 42.
[12] DONG Jun-qing, ZHU Tie-quan, MAO Zhen-wei, et al(董俊卿, 朱铁权, 毛振伟, 等). Southeast Culture(东南文化), 2006, (1): 24.
[13] CHEN Xiao-feng, MA Qing-lin, ZHAO Guang-tian, et al(陈晓峰, 马清林, 赵广田, 等). Journal of Lanzhou University·Natural Sciences)(兰州大学学报·自然科学版), 2000, 36(5): 76.
[14] YAN Xiao-qin, LIU Yi-kun, LI Li, et al(严小琴, 刘逸堃, 李 立, 等). Journal of Chinese Electron Microscopy Society(电子显微学报), 2013, 32(5): 403.
[15] WANG Xue-pei, ZHAO Hong-xia, LI Qing-hui, et al(王雪培,赵虹霞,李青会,等). Acta Optica Sinica(光学学报), 2015, 35(10): 103003.
[16] Liu Song, Li Qinghui, Gan Fuxi, et al. X-Ray Spectrometry, 2011, 40(5): 364.
[17] Zhao H X, Li Q H, Liu S, et al. Journal of Raman Spectroscopy, 2013, 44(4): 643.
[18] LI Wen-yi, ZHANG Ting, YANG Jie(李文怡, 张 蜓, 杨 洁). Relics and Museolgy(文博), 2012, (6): 78.
[19] WANG Xue-pei, LI Qing-hui(王雪培,李青会). Spectroscopy and Spectroscopy Analysis(光谱学与光谱分析),2016, 36(12): 4045.
[20] de Faria D L A, Venncio Silva S, de Oliveira M T. Journal of Raman Spectroscopy,1997,(28): 873.
[21] Bikiaris D, Sister Daniilia, Sotiropoulou S, et al. Spectrochimica Acta Part A, 2000, 56: 3.
[22] WU Juan-xia, XU Hua, ZHANG Jin(吴娟霞, 徐 华, 张 锦). Acta Chimica Sinica(化学学报),2014, (72): 301.
[23] WANG Jian-qiang, XIN Bai-fu, YU Hai-tao, et al(王建强, 辛柏福, 于海涛, 等). Chemical Journal of Chinese Universities(高等学校化学学报), 2003, (24): 1237.
[24] MA Yan-ping, LIU Ying-ming(马艳平, 刘英明). Analytical Instrumentation(分析仪器), 2009, (6).
[25] MA Qing-lin, HU Zhi-de, LI Zui-xiong,et al(马清林, 胡之德,李最雄,等). Cultural Relic(文物), 2001,(8): 84. |
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