光谱学与光谱分析 |
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A Study on Quantitative Evaluation of Damage in Conservation of Ceramics from HuaguangjiaoⅠShipwreck with ICP-AES |
LI Wen-jing1, 2, CHEN Yue1, 2, LI Nai-sheng3, LI Bin4, LUO Wu-gan1, 2* |
1. Key Lab of Vertebrate Evolution and Human Origin of Chinese Academy of Sciences, Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences, Beijing 100044, China 2. Department of Scientific History and Archaeometry, University of Chinese Academy of Sciences, Beijing 100049, China 3. Chinese Academy of Cultural Heritage, Beijing 100029, China 4. Key Scientific Research Base of Ancient Polychrome Pottery Conservation, Emperor Qin’s Terra-cotta Warriors & Horses Mnseum, Xi’an 710600, China |
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Abstract ICP-AES was used to determine the elemental composition of solutions in different conservation steps for understanding the impact of cleaning agents on ceramics from HuaguangjiaoⅠshipwreck. The results showed that high content in solutionof Al,Fe,Mg ions, which can be indexes to reflect the damage in conservation of ceramics. According to these indexes, we discovered that agents of strong cleaning ability bring more damage to ceramic samples. Meanwhile, the stateof preservation of the ceramics was closely related to the damage in conservation. Ceramics in an excellent state of preservation endure less damage than that in bad state. Wealso found that each cleaning agent cause certain degree of damage on porcelains, even neutral reagent, like deionized water. Moreover, moderate cleaning reagent, when using a long time, bring the same degree of damage as the strong acid. Therefore, in actual protection procedure, for conservation ceramics safe and effective, damage of each cleaning agents and cumulative damage should be considered.
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Received: 2014-04-14
Accepted: 2014-07-21
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Corresponding Authors:
LUO Wu-gan
E-mail: xiahua@ucas.ac.cn
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[1] Robinson W S. International Journal of Nautical Archaeology,1981,10 (1): 3. [2] Norquest S. Anagpic,2008,12: 1. [3] Gheorghe S V. Museum Microclimates,2007,11: 31. [4] Casaletto M P, Ingo G M, Riccucci C, et al. Applied Physics A: Materials Science & Processing,2008,92:35. [5] WANG Hui-zhen(王蕙贞). Science of Conservation Materials(文物保护材料学). Xi’an: Northwestern University Press(西安:西北大学出版社),1995. [6] ZHOU Shuang-lin(周双林). Cultural Relics of Central China(中原文物),1995,(02):111. [7] WANG Hui-zhen(王蕙贞). Science of Conservation(文物保护学). Beijing: Cultural Relics Publishing House(北京:文物出版社),2009. [8] HU Dong-po, ZHANG Hong-yan(胡东坡,张红燕). Science of Conservation and Archaeology(文物保护与考古科学),2010,22(1):49. [9] LI Jian-an(栗建安). International Museum(国际博物馆),2008,(4):106. [10] SUN Jian(孙 建). China Cultural Heritage(中国文化遗产),2007,(4):32. [11] LIU Yi(刘 毅). Huaxia Archaeology(华夏考古),2003,(3) :49. [12] ZHANG Fu-kang, ZHANG Zhi-gang(张福康,张志刚). Journal of the Chinese Ceramic Society(硅酸盐学报),1980,8(1):9. |
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