Chemical Analysis of Historical Materials and Cultural Heritage Objects
Authors
Govt. College Una (Himachal Pradesh)
NSCBM Govt. College Hamirpur (Himachal Pradesh)
NSCBM Govt. College Hamirpur (Himachal Pradesh)
NSCBM Govt. College Hamirpur (Himachal Pradesh)
Article Information
DOI: 10.51584/IJRIAS.2025.10120060
Subject Category: Chemistry
Volume/Issue: 10/12 | Page No: 743-753
Publication Timeline
Submitted: 2025-12-25
Accepted: 2025-12-30
Published: 2026-01-16
Abstract
ABSTRACT
The chemical analysis of historical materials and cultural heritage objects plays a vital role in understanding their composition, provenance, manufacturing techniques, and state of preservation. Short communication studies in this field focus on the rapid dissemination of significant analytical findings obtained from artworks, archaeological artifacts, manuscripts, and architectural materials. This article highlights the application of modern analytical techniques such as X-ray fluorescence (XRF), Fourier-transform infrared spectroscopy (FTIR), Raman spectroscopy, scanning electron microscopy coupled with energy-dispersive X-ray analysis (SEM–EDX), and chromatography in the non-destructive or minimally invasive examination of heritage objects. Emphasis is placed on the identification of pigments, binders, corrosion products, and degradation pathways that influence conservation strategies. The integration of chemical data with historical and archaeological context provides valuable insights into ancient technologies and trade practices while supporting informed conservation and restoration decisions. By presenting concise yet impactful results, this short communication demonstrates how targeted chemical analyses can significantly contribute to the preservation and interpretation of cultural heritage, while adhering to the ethical requirement of minimal intervention on irreplaceable historical materials.
Keywords
Cultural Heritage Materials, Chemical Analysis, Non-Destructive Analytical Techniques
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References
1. de Castro, M. L., & Jurado-López, A. (2019). The role of analytical chemists in the research on the cultural heritage. Talanta, 205, 120106. [Google Scholar] [Crossref]
2. Madariaga, J. M. (2015). Analytical chemistry in the field of cultural heritage. Analytical Methods, 7(12), 4848-4876 [Google Scholar] [Crossref]
3. Bertrand, L., Thoury, M., Gueriau, P., Anheim, É., & Cohen, S. (2021). Deciphering the chemistry of cultural heritage: targeting material properties by coupling spectral imaging with image analysis. Accounts of Chemical Research, 54(13), 2823-2832. [Google Scholar] [Crossref]
4. Janssens, K., & Van Grieken, R. (Eds.). (2004). Non-destructive micro analysis of cultural heritage materials (Vol. 42). Elsevier. [Google Scholar] [Crossref]
5. Aucouturier, M., & Darque-Ceretti, E. (2007). The surface of cultural heritage artefacts: physicochemical investigations for their knowledge and their conservation. Chemical Society Reviews, 36(10), 1605-1621. [Google Scholar] [Crossref]
6. Towarek, A., Halicz, L., Matwin, S., & Wagner, B. (2024). Machine learning in analytical chemistry for cultural heritage: A comprehensive review. Journal of Cultural Heritage, 70, 64-70. [Google Scholar] [Crossref]
7. Mazzeo, R., Roda, A., & Prati, S. (2011). Analytical chemistry for cultural heritage: a key discipline in conservation research. Analytical and bioanalytical chemistry, 399(9), 2885-2887. [Google Scholar] [Crossref]
8. Gates, G. A. (2014). Discovering the material secrets of art: Tools of cultural heritage science. Am. Ceram. Soc. Bull, 93, 20-27. [Google Scholar] [Crossref]
9. Greenberg, A. (2002). The art of chemistry: myths, medicines, and materials. John Wiley & Sons. [Google Scholar] [Crossref]
10. Chalupa, R., & Nesměrák, K. (2021). Analytical chemistry reveals secrets of alchemy. Monatshefte für Chemie-Chemical Monthly, 152(9), 1019-1032. [Google Scholar] [Crossref]
11. Schummer, J., & Spector, T. I. (2007). The visual image of chemistry: Perspectives from the history of art and science. In The public image of chemistry (pp. 213-257). [Google Scholar] [Crossref]
12. Vovk, Y., Merezhko, N., Indutnyi, V., Pirkovich, K., & Lytvynenko, Y. (2022). Determining Dangerous Chemicals on the Surface of Metallic Historical Artifacts. Eastern-European Journal of Enterprise Technologies, 6(12), 120. [Google Scholar] [Crossref]
13. Bensaude-Vincent, B., & Stengers, I. (1996). A history of chemistry. Harvard University Press. [Google Scholar] [Crossref]
14. Watts, S., Abbott, D., Crombie, D., Gunn, A., & Pensée, A. L. (2008). Science revealed: the hidden story of objects. Studies in Conservation, 53(sup1), 146-150. [Google Scholar] [Crossref]
15. Giuffrida, M. G., Mazzoli, R., & Pessione, E. (2018). Back to the past: deciphering cultural heritage secrets by protein identification. Applied microbiology and biotechnology, 102(13), 5445-5455. [Google Scholar] [Crossref]
16. Prus, B., Wilkosz-Mamcarczyk, M., & Salata, T. (2020). Landmarks as cultural heritage assets affecting the distribution of settlements in rural areas—An analysis based on lidar dtm, digital photographs, and historical maps. Remote sensing, 12(11), 1778. [Google Scholar] [Crossref]
17. Rodriguez-Simón, L., Navas, N., & Manzano, E. (2010). Chemistry in cultural heritage and cultural heritage in chemistry. Research and education. Painter and sculptor: Alonso Cano’s projects. In EDULEARN10 Proceedings (pp. 1062-1070). IATED. [Google Scholar] [Crossref]
18. Sharma, B. K. (1981). Instrumental methods of chemical analysis. Krishna Prakashan Media. [Google Scholar] [Crossref]
19. Sangster, A. J. (2018). Fundamentals of Electromagnetic Radiation. In Compact Slot Array Antennas for Wireless Communications (pp. 35-56). Cham: Springer International Publishing. [Google Scholar] [Crossref]
20. Zlotorzynski, A. (1995). The application of microwave radiation to analytical and environmental chemistry. Critical Reviews in Analytical Chemistry, 25(1), 43-76. [Google Scholar] [Crossref]
21. Drdácký, M., Ševčík, R., Frankeová, D., Koudelková, V., Buzek, J., Eisler, M., & Valach, J. (2024). Degradation mechanisms of mortar and plaster layers. Materials, 17(14), 3419. [Google Scholar] [Crossref]
22. Brysbaert, A. N. (2004). Technology and social agency in Bronze Age Aegean and Eastern Mediterranean painted plaster. University of Glasgow (United Kingdom). [Google Scholar] [Crossref]
23. Derry, J. (2012). Investigating Shellac. Project-Based Masters Thesis. [Google Scholar] [Crossref]
24. Ahluwalia, V. K. (2023). Infrared spectroscopy. In Instrumental Methods of Chemical Analysis (pp. 179-231). Cham: Springer Nature Switzerland. [Google Scholar] [Crossref]
25. Bitossi, G., Giorgi, R., Mauro, M., Salvadori, B., & Dei, L. (2005). Spectroscopic techniques in cultural heritage conservation: a survey. Applied Spectroscopy Reviews, 40(3), 187-228. [Google Scholar] [Crossref]
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