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Recent Advances in the Application of the Field-Portable Hyperspectral Radiometer to Characterize Materials Concerning Cultural Heritage |
WANG Cong1, 2, Mara Camaiti3, LIU Dai-yun4, TIE Fu-de2, 5, CAO Yi-jian5, 6* |
1. China-Central Asia “The Belt and Road” Joint Laboratory on Human and Environment Research (Northwest University), Xi'an 710127, China
2. Key Laboratory of Cultural Heritage Research and Conservation (Northwest University), Ministry of Education, Xi'an 710127, China
3. CNR-Institute of Geosciences and Earth Resources, Florence 50121, Italy
4. Shaanxi Provincial Institute of Archaeology, Xi'an 710043, China
5. Key Laboratory of Archaeological Exploration and Cultural Heritage Conservation Technology (Northwestern Polytechnical University), Ministry of Education, Xi'an 710072, China
6. Institute of Culture and Heritage, Northwestern Polytechnical University, Xi'an 710072, China
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Abstract Cultural heritage is the precious, non-renewable cultural resource of all humanity. Due to the preciousness of cultural heritage and also based on the basic principle of minimal intervention in heritage conservation, non-destructive analysis has always been the most important technology for materials characterization in the field of heritage science (e.g. studies on the original manufacturing process, deterioration mechanism and conservation/restoration technology). Therefore, developing and applying novel non-destructive analysis technology is an indispensable research direction in heritage science. Recently, the field-portable hyperspectral radiometer, originating from remote sensing as a light energy radiometer, has shown great application potential in analyzing heritage objects and has already been successfully applied in restoring ancient stone architecture, paintings, and others. As a non-invasive spectral technique that does not require sampling, the field-portable hyperspectral radiometer can acquire a full-band, high-resolution reflectance spectrum covering visible-near-infrared and shortwave infrared bands (350~2 500 nm) in a very short time. At the same time, it is highly portable. It can be used in the field or archaeological sites regardless of the environmental conditions. Moreover, remote sensing technology can be used to realize remote transmission and analysis of spectral data during spectral acquisition. All these characteristics are unique advantages for their application in characterizing artworks. This paper introduces the equipment type and characteristics of the field-portable hyperspectral radiometer commonly used first. The application status in the qualitative and quantitative analysis of organic/inorganic artworks, the analysis of conservation materials, and the in situ and real-time monitoring of the conservation/restoration process in the past ten years are reviewed afterwards. Then, two key problems that affect the accuracy and efficiency of using this technique are discussed in depth, i.e. the specification of spectral pre-treatment and the establishment of standard spectra databases. Finally, the development trend of this technique is forecasted. It is expected to have broad prospects in analysing fragile organic heritage objects, combining application of various analysis techniques and quantitative analysis.
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Received: 2023-03-14
Accepted: 2023-07-19
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Corresponding Authors:
CAO Yi-jian
E-mail: yijian.cao@nwpu.edu.cn
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[1] Tejedor B, Lucchi E, Bienvenido-Huertas D, et al. Energy and Buildings, 2022, 263: 112029.
[2] Camaiti M, Benvenuti M, Costagliola P, et al. Hyperspectral Sensors for the Characterization of Cultural Heritage Surfaces, in Sensing the Past, Cham: Springer Nature, 2017. 289.
[3] Ricciardi P. UV-Vis-Near IR Reflectance Spectrophotometry in a Museum Environment, Spectroscopy, in Diffraction and Tomography in Art and Heritage Science, Amsterdam: Elsevier, 2021. 103.
[4] Liang H. Applied Physics A, 2012, 106(2): 309.
[5] DENG Biao, GUO Hua-dong, WANG Chang-lin, et al(邓 飚,郭华东,王长林,等). Journal of Remote Sensing(遥感学报), 2010, 14(1): 187.
[6] Camaiti M, Vettori S, Benvenuti M, et al. Journal of Geophysics and Engineering, 2011, 8: S126.
[7] Clark R N. Remote Sensing for the Earth Sciences: Manual of Remote Sensing, in A. N. Rencz, Spectroscopy of Rocks and Minerals, and Principles of Spectroscopy, New York: John Wiley & Sons, Inc, 1999. 3.
[8] Ramakrishnan D, Bharti R. Current Science, 2015, 108: 879.
[9] Workman J, Weyer L. Practical Guide to Interpretive Near-Infrared Spectroscopy. Boca Raton: CRC Press, 2007. 1.
[10] Krzysztof B B. NIR News, 2021, 32: 15.
[11] Goetz A F H, Vane G, Solomon B N, et al. Science, 1985, 228: 1147.
[12] Cucci C, Delaney J K, Picollo M. Accounts of Chemical Research, 2016, 49: 2070.
[13] Picollo M, Cucci C, Casini A, et al. Sensors, 2020, 20(10): 2843.
[14] Cucci C, Casini A. Hyperspectral Imaging for Artworks Investigation, in Data Handling in Science and Technology, Amsterdam: Elsevier, 2019. 583.
[15] Gao Z, Du M, Cao N, et al. Heritage Science, 2023, 11: 8.
[16] LIN Wan, PENG Yan-kun, WANG Cai-ping(林 琬,彭炎昆,王彩萍). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2014, 30(7): 243.
[17] O'Brien N A, Hulse C A, Friedrich D M, et al. Proceedings of SPIE, 2012, 8374: 837404.
[18] Catelli E, Sciutto G, Prati S, et al. Talanta, 2020, 218: 121112.
[19] WANG Cong, CAMAITI Mara, TIE Fu-de, et al(王 聪,CAMAITI Mara,铁付德,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2021, 41(9): 2886.
[20] Campbell J B, Wynne R H. Introduction to Remote Sensing. 5th ed. New York: The Guilford Press, 2011. 34.
[21] Suzuki A, Vettori S, Giorgi S, et al. Journal of Cultural Heritage, 2018, 32: 30.
[22] Gaffey S J. American Mineralogist, 1986, 71: 151.
[23] Cimino D, Falchi L, Corradini M, et al. Reflectance Spectroscopy as a Non-Invasive Technique for the Preliminary Characterization of Soluble Salts on Historical Masonries, in Advanced Nondestructive and Structural Techniques for Diagnosis, Redesign and Health Monitoring for the Preservation of Cultural Heritage, Cham: Springer Nature, 2022. 28.
[24] Aceto M, Agostino A, Fenoglio G, et al. Analytical Methods, 2014, 6: 1488.
[25] Horn K R, Walker G, Winton V, et al. Journal of Archaeological Science: Reports, 2020, 34: 2617.
[26] Perino M, Pronti L, Di Forti L G, et al. Minerals, 2021, 11: 771.
[27] Radpour R, Delaney J K, Kakouli I. Sensors, 2022, 22(5): 1915.
[28] Liu W, Li M, Wu N, et al. Journal of Cultural Heritage, 2021, 49: 19.
[29] Pallipurath A R, Skelton J M, Ricciardi P, et al. Talanta, 2016, 154: 63.
[30] Lyu S, Liu Y, Hou M, et al. Heritage Science, 2020, 8: 31.
[31] Ricciardi P, Delaney J K, Facini M, et al. Angewandte Chemie International Edition, 2012, 51: 5607.
[32] Dooley K A, Lomax S, Zeibel J G, et al. Analyst, 2013, 138: 4838.
[33] Gabrieli F, Dooley K A, Facini M, et al. Science Advances, 2019, 5: eaaw7794.
[34] Pallipurath A R, Skelton J M, Ricciardi P, et al. Journal of Raman Spectroscopy, 2013, 44: 866.
[35] Wang C, Salvatici T, Camaiti M, et al. EGU General Assembly,2016, 18: 18255.
[36] Horn K R. Journal of Archaeological Science: Reports, 2018, 21: 10.
[37] Amato S R, Burnstock A, Michelin A. Sensors, 2020, 20: 7125.
[38] Zhao H, Wang Y, Liu S, et al. Journal of Archaeological Science, 2019, 111: 105026.
[39] DING Li, GONG Tian-yi, YANG Qin, et al(丁 莉,龚天怡,杨 琴,等). Science of Conservation and Archaeology(文物保护与考古科学), 2021, 33(4): 128.
[40] Vettori S, Pecchioni E, Camaiti M, et al. EGU General Assembly,2012, 14: 9459.
[41] Wang C, Cao Y, Tie F, et al. Coatings, 2021, 11: 1315.
[42] Vettori S, Verrucchi M, Di Benedetto F, et al. Journal of Cultural Heritage, 2021, 49: 79.
[43] Maynez-Rojas M A, Casanova-Gonzalez E, Ruvalcaba-Sil J L. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2017, 178: 239.
[44] Pottier F, Kwimang S, Michelin A, et al. Analytical Methods, 2017, 9: 5997.
[45] ZHANG Chen-feng, HU Yun-gang, HOU Miao-le, et al(张陈峰,胡云岗,候妙乐,等). Geomatics World(地理信息世界), 2017, 25(3): 119.
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