Review
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Year 2024, Volume: 11 Issue: 3, 24 - 29, 28.09.2024
https://doi.org/10.30897/ijegeo.1478498

Abstract

Project Number

-

References

  • Albini, M., Letardi, P., Mathys, L., Brambilla, L., Schröter, J., Junier, P., Joseph, E. (2018). Comparison of a bio-based corrosion inhibitor versus benzotriazole on corroded copper surfaces. Corrosion science, 143, 84-92.
  • Al-Shamari, A. R., Prakash, S., Al-Mithin, A. W., Biedermann, A. J., Islam, M., Mathew, A. (2013). Some empirical observations about bacteria proliferation and corrosion damage morphology in Kuwait oilfield waters. In nace corrosion, 2748.
  • Artesani, A., Di Turo, F., Zucchelli, M., Traviglia, A. (2020). Recent advances in protective coatings for cultural heritage–an overview. Coatings, 10(3), 217.
  • Ashley-Smith, J. (2013). Risk assessment for object conservation, New yourk: Taylor & Francis Aufray, M., Josse, C., Balbo, A., Monticelli, C., Švara Fabjan, E., Škrlep, L., Kosec, T., and Kete, M. (2019). Practical adhesion measurements of protective coatings on bronze by three-point bending test. Journal of Coatings Technology and Research, 16, 1465-1477.
  • Baglioni, M., Alterini, M., Chelazzi, D., Giorgi, R., Baglioni, P. (2019). Removing polymeric coatings with nanostructured fluids: Influence of substrate, nature of the film, and application methodology. Frontiers in Materials, 6, 311.
  • Baglioni, M., Guaragnone, T., Mastrangelo, R., Sekine, F. H., Ogura, T., Baglioni, P. (2020). Nonionic surfactants for the cleaning of works of art: insights on acrylic polymer films dewetting and artificial soil removal. ACS applied materials & interfaces, 12(23), 26704-26716.
  • Baglioni, M., Montis, C., Brandi, F., Guaragnone, T., Meazzini, I., Baglioni, P., Berti, D. (2017). Dewetting acrylic polymer films with water/propylene carbonate/surfactant mixtures–implications for cultural heritage conservation. Physical Chemistry Chemical Physics, 19(35), 23723-23732.
  • Baglioni, M., Montis, C., Chelazzi, D., Giorgi, R., Berti, D., Baglioni, P. (2018). Polymer film dewetting by water/surfactant/good‐solvent mixtures: a mechanistic insight and its implications for the conservation of cultural heritage. Angewandte Chemie, 130(25), 7477-7481.
  • Baglioni, M., Poggi, G., Chelazzi, D., Baglioni, P. (2021). Advanced materials in cultural heritage conservation. Molecules, 26(13), 3967.
  • Baglioni, M., Poggi, G., Ciolli, G., Fratini, E., Giorgi, R., Baglioni, P. (2018). A Triton X-100-based microemulsion for the removal of hydrophobic materials from works of art: SAXS characterization and application. Materials, 11(7), 1144.
  • Barouni, K., Kassale, A., Albourine, A., Jbara, O., Hammouti, B., Bazzi, L. (2014). Amino acids as corrosion inhibitors for copper in nitric acid medium: Experimental and theoretical study. J. Mater. Environ. Sci, 5(2), 456-463.
  • Bartoletti, A., Maor, T., Chelazzi, D., Bonelli, N., Baglioni, P., Angelova, L. V., Ormsby, B. A. (2020). Facilitating the conservation treatment of Eva Hesse’s Addendum through practice-based research, including a comparative evaluation of novel cleaning systems. Heritage Science, 8, 1-27.
  • Behpour, M., Ghoreishi, S. M., Khayatkashani, M., Soltani, N. J. M. C. (2012). Green approach to corrosion inhibition of mild steel in two acidic solutions by the extract of Punica granatum peel and main constituents. Materials Chemistry and Physics, 131(3), 621-633.
  • Bernard, M. C. and S. Joiret (2009). Understanding corrosion of ancient metals for the conservation of cultural heritage. Electrochimica Acta, 54(22), 5199-5205.
  • Bertholon, R. (2007). Archaeological metal artefacts and conservation issues: long-term corrosion studies. In corrosion of metallic heritage artefacts, 31-40.
  • Bonelli, N., Montis, C., Mirabile, A., Berti, D., Baglioni, P. (2018). Restoration of paper artworks with microemulsions confined in hydrogels for safe and efficient removal of adhesive tapes. Proceedings of the National Academy of Sciences, 115(23): 5932-5937.
  • Burt, V., Steve L., Bonnie R. S. (2015). Corrosion in the petrochemical industry. Materials Park: ASM International, 75-81
  • Caple, C. (2008). Preservation in situ: the future for archaeological conservators? Studies in Conservation, 53(sup1), 214-217.
  • Casoli, A., Di Diego, Z., Isca, C. (2014). Cleaning painted surfaces: evaluation of leaching phenomenon induced by solvents applied for the removal of gel residues. Environmental Science and Pollution Research, 21, 13252-13263.
  • Davison, S. (1984). A review of adhesives and consolidants used on glass antiquities. Studies in Conservation, 29(sup1), 191-194.
  • Declich, F., Pennaccini, C. (2014). Cooperating for Cultural Heritage Conservation. JUNCO| Journal of UNiversities and international development COoperation, (1).
  • El-Haddad, M. N. (2013). Chitosan as a green inhibitor for copper corrosion in acidic medium. International journal of biological macromolecules, 55, 142-149.
  • Eppich, R. and J. L. G. Grinda (2019). Sustainable financial management of tangible cultural heritage sites. Journal of Cultural Heritage Management and Sustainable Development, 9(3), 282-299.
  • Faraldi, F., Cortese, B., Caschera, D., Di Carlo, G., Riccucci, C., De Caro, T., Ingo, G. M. (2017). Smart conservation methodology for the preservation of copper-based objects against the hazardous corrosion. Thin Solid Films, 622, 130-135.
  • Figueira, R. B., Silva, C. J., Pereira, E. V. (2015). Organic–inorganic hybrid sol–gel coatings for metal corrosion protection: a review of recent progress. Journal of Coatings Technology and Research, 12, 1-35.
  • Gençer, G. M. (2021). The Importance of Corrosion Protection of Metal-Containing Historical Artifacts and Common Methods Used for Preservation. International Journal of Environment and Geoinformatics, 8(4), 514-520.
  • Hollander, O. and R. C. May (1985). The chemistry of azole copper corrosion inhibitors in cooling waters. Corrosion 41(1), 39-45.
  • Högberg, A. and C. Holtorf (2021). Cultural heritage and the future, Routledge.
  • Ismail, K. M. (2007). Evaluation of cysteine as environmentally friendly corrosion inhibitor for copper in neutral and acidic chloride solutions. Electrochimica Acta, 52(28), 7811-7819.
  • Khan, P. F., Shanthi, V., Babu, R. K., Muralidharan, S., Barik, R. C. (2015). Effect of benzotriazole on corrosion inhibition of copper under flow conditions. Journal of Environmental Chemical Engineering 3(1), 10-19.
  • Koob, S. (2009). Paraloid B-72®: 25 years of use as a consolidant and adhesive for ceramics and glass. Holding it All Together Ancient and Modern Approaches to Joining, Repairs and Consolidation, 113-119.
  • Masi, G., Josse, C., Esvan, J., Chiavari, C., Bernardi, E., Martini, C., Bignozi, C.M., Robbiola, L. (2019). Evaluation of the protectiveness of an organosilane coating on patinated Cu-Si-Mn bronze for contemporary art. Progress in Organic Coatings, 127, 286-299.
  • Mastrangelo, R., Chelazzi, D., Poggi, G., Fratini, E., Pensabene Buemi, L., Petruzzellis, M. L., Baglioni, P. (2020). Twin-chain polymer hydrogels based on poly (vinyl alcohol) as new advanced tool for the cleaning of modern and contemporary art. Proceedings of the National Academy of Sciences, 117(13), 7011-7020.
  • Meng, B., Mueller, U., Garcia, O., Malaga, K. (2014). Performance of a new anti-graffiti agent used for immovable cultural heritage objects. International Journal of Architectural Heritage, 8(6), 820-834.
  • Moffett, D. L. (1996). Wax coatings on ethnographic metal objects: justifications for allowing a tradition to wane. Journal of the american institute for conservation, 35(1), 1-7.
  • Muresan, L., Oniciu, L., Froment, M., & Maurin, G. (1992). Inhibition of lead electrocrystallization by organic additives. Electrochimica acta, 37(12), 2249-2254.
  • Pickard, R. (2001). Policy and law in heritage conservation . Londonand New york, Taylor & Francis. Protection, E. C. (2018). Hybrid Sol-Gel Coatings. Production, Properties, and Applications of High Temperature Coatings, 334.
  • Robinson, W. S. (1982). The corrosion and preservation of ancient metals from marine sites. International Journal of Nautical Archaeology, 11(3): 221-231.
  • Sadat‐Shojai, M., Ershad‐Langroudi, A. (2009). Polymeric coatings for protection of historic monuments: Opportunities and challenges. Journal of Applied Polymer Science, 112(4), 2535-2551.
  • Salzano de Luna, M., Buonocore, G. G., Giuliani, C., Messina, E., Di Carlo, G., Lavorgna, M., Ambrosio, L., Ingo, G. M. (2018). Long‐lasting efficacy of coatings for bronze artwork conservation: the key role of layered double hydroxide nanocarriers in protecting corrosion inhibitors from photodegradation. Angewandte Chemie International Edition, 57(25), 7380-7384.
  • Sesana, E., Gagnon, A. S., Ciantelli, C., Cassar, J., Hughes, J. J. (2021). Climate change impacts on cultural heritage: A literature review. Wiley Interdisciplinary Reviews: Climate Change, 12(4), e710.
  • Sloggett, R. (2022). Conservation skills. Journal of the Institute of Conservation, 45(3), 157-172.
  • Stulik, D. (2004). Solvent gels for the cleaning of works of art: the residue question. Getty Publications.
  • Telegdi, J., Shaban, A., Trif, L. (2017). Microbiologically influenced corrosion (MIC). Trends in oil and gas corrosion research and technologies, 191-214.
  • Wang, T., Wang, J., Wu, Y. (2015). The inhibition effect and mechanism of l-cysteine on the corrosion of bronze covered with a CuCl patina. Corrosion Science, 97, 89-99.
  • Watkinson, D. (2010). 4.43 Preservation of Metallic Cultural Heritage. Corrosion Management, 3307-3340.
  • Winther, T., Bannerman, J., Skogstad, H., Johansson, M. K., Jacobson, K., Samuelsson, J. (2015). Adhesives for adhering polystyrene plastic and their long-term effect. Studies in Conservation, 60(2), 107-120.
  • Wolbers, R. (2000). Cleaning painted surfaces: aqueous methods.
  • Yarime, M., Trencher, G., Mino, T., Scholz, R. W., Olsson, L., Ness, B., Frantzeskaki, N., Rotmans, J. (2012). Establishing sustainability science in higher education institutions: towards an integration of academic development, institutionalization, and stakeholder collaborations. Sustainability Science, 7, 101-113.
  • Yadav, S., Raman, A. P., Singh, M. B., Massey, I., Singh, P., Verma, C., AlFantazi, A. (2024). Green nanoparticles for advanced corrosion protection: Current perspectives and future prospects. Applied Surface Science Advances, 21, 100605.

A Review on Conservational Methodologies of Tangible Cultural Artifacts from Environmental Corrosion

Year 2024, Volume: 11 Issue: 3, 24 - 29, 28.09.2024
https://doi.org/10.30897/ijegeo.1478498

Abstract

Tangible cultural heritage are invaluable assets inherited from our ancestors, encompassing transformative skills, culture, tradition, knowledge and practice, passed down by generations to generation. It is sad to say that, these assets are at brink of deterioration, and vandalism from both pernicious natural forces and relentless time laps. There is an urgent need of preserving and carefully transferring these treasures to the future generations. The main objective of our study is to provide basic knowledge for the conservation of cultural artifacts. With this investigation, we lay stress on the significance of cultural artifacts, delve the factors influencing corrosion, talk about cleaning methods and stressing the use of inhibitor or protective coating to shield them from further decay. Our study emphasizes the urgent need of development of new methodologies and strategies to safeguard these assets from ruinous events. In addition, it also present ongoing efforts applied in transmission and preservation of these metallic artifacts in their original form.

Ethical Statement

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Supporting Institution

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Project Number

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Thanks

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References

  • Albini, M., Letardi, P., Mathys, L., Brambilla, L., Schröter, J., Junier, P., Joseph, E. (2018). Comparison of a bio-based corrosion inhibitor versus benzotriazole on corroded copper surfaces. Corrosion science, 143, 84-92.
  • Al-Shamari, A. R., Prakash, S., Al-Mithin, A. W., Biedermann, A. J., Islam, M., Mathew, A. (2013). Some empirical observations about bacteria proliferation and corrosion damage morphology in Kuwait oilfield waters. In nace corrosion, 2748.
  • Artesani, A., Di Turo, F., Zucchelli, M., Traviglia, A. (2020). Recent advances in protective coatings for cultural heritage–an overview. Coatings, 10(3), 217.
  • Ashley-Smith, J. (2013). Risk assessment for object conservation, New yourk: Taylor & Francis Aufray, M., Josse, C., Balbo, A., Monticelli, C., Švara Fabjan, E., Škrlep, L., Kosec, T., and Kete, M. (2019). Practical adhesion measurements of protective coatings on bronze by three-point bending test. Journal of Coatings Technology and Research, 16, 1465-1477.
  • Baglioni, M., Alterini, M., Chelazzi, D., Giorgi, R., Baglioni, P. (2019). Removing polymeric coatings with nanostructured fluids: Influence of substrate, nature of the film, and application methodology. Frontiers in Materials, 6, 311.
  • Baglioni, M., Guaragnone, T., Mastrangelo, R., Sekine, F. H., Ogura, T., Baglioni, P. (2020). Nonionic surfactants for the cleaning of works of art: insights on acrylic polymer films dewetting and artificial soil removal. ACS applied materials & interfaces, 12(23), 26704-26716.
  • Baglioni, M., Montis, C., Brandi, F., Guaragnone, T., Meazzini, I., Baglioni, P., Berti, D. (2017). Dewetting acrylic polymer films with water/propylene carbonate/surfactant mixtures–implications for cultural heritage conservation. Physical Chemistry Chemical Physics, 19(35), 23723-23732.
  • Baglioni, M., Montis, C., Chelazzi, D., Giorgi, R., Berti, D., Baglioni, P. (2018). Polymer film dewetting by water/surfactant/good‐solvent mixtures: a mechanistic insight and its implications for the conservation of cultural heritage. Angewandte Chemie, 130(25), 7477-7481.
  • Baglioni, M., Poggi, G., Chelazzi, D., Baglioni, P. (2021). Advanced materials in cultural heritage conservation. Molecules, 26(13), 3967.
  • Baglioni, M., Poggi, G., Ciolli, G., Fratini, E., Giorgi, R., Baglioni, P. (2018). A Triton X-100-based microemulsion for the removal of hydrophobic materials from works of art: SAXS characterization and application. Materials, 11(7), 1144.
  • Barouni, K., Kassale, A., Albourine, A., Jbara, O., Hammouti, B., Bazzi, L. (2014). Amino acids as corrosion inhibitors for copper in nitric acid medium: Experimental and theoretical study. J. Mater. Environ. Sci, 5(2), 456-463.
  • Bartoletti, A., Maor, T., Chelazzi, D., Bonelli, N., Baglioni, P., Angelova, L. V., Ormsby, B. A. (2020). Facilitating the conservation treatment of Eva Hesse’s Addendum through practice-based research, including a comparative evaluation of novel cleaning systems. Heritage Science, 8, 1-27.
  • Behpour, M., Ghoreishi, S. M., Khayatkashani, M., Soltani, N. J. M. C. (2012). Green approach to corrosion inhibition of mild steel in two acidic solutions by the extract of Punica granatum peel and main constituents. Materials Chemistry and Physics, 131(3), 621-633.
  • Bernard, M. C. and S. Joiret (2009). Understanding corrosion of ancient metals for the conservation of cultural heritage. Electrochimica Acta, 54(22), 5199-5205.
  • Bertholon, R. (2007). Archaeological metal artefacts and conservation issues: long-term corrosion studies. In corrosion of metallic heritage artefacts, 31-40.
  • Bonelli, N., Montis, C., Mirabile, A., Berti, D., Baglioni, P. (2018). Restoration of paper artworks with microemulsions confined in hydrogels for safe and efficient removal of adhesive tapes. Proceedings of the National Academy of Sciences, 115(23): 5932-5937.
  • Burt, V., Steve L., Bonnie R. S. (2015). Corrosion in the petrochemical industry. Materials Park: ASM International, 75-81
  • Caple, C. (2008). Preservation in situ: the future for archaeological conservators? Studies in Conservation, 53(sup1), 214-217.
  • Casoli, A., Di Diego, Z., Isca, C. (2014). Cleaning painted surfaces: evaluation of leaching phenomenon induced by solvents applied for the removal of gel residues. Environmental Science and Pollution Research, 21, 13252-13263.
  • Davison, S. (1984). A review of adhesives and consolidants used on glass antiquities. Studies in Conservation, 29(sup1), 191-194.
  • Declich, F., Pennaccini, C. (2014). Cooperating for Cultural Heritage Conservation. JUNCO| Journal of UNiversities and international development COoperation, (1).
  • El-Haddad, M. N. (2013). Chitosan as a green inhibitor for copper corrosion in acidic medium. International journal of biological macromolecules, 55, 142-149.
  • Eppich, R. and J. L. G. Grinda (2019). Sustainable financial management of tangible cultural heritage sites. Journal of Cultural Heritage Management and Sustainable Development, 9(3), 282-299.
  • Faraldi, F., Cortese, B., Caschera, D., Di Carlo, G., Riccucci, C., De Caro, T., Ingo, G. M. (2017). Smart conservation methodology for the preservation of copper-based objects against the hazardous corrosion. Thin Solid Films, 622, 130-135.
  • Figueira, R. B., Silva, C. J., Pereira, E. V. (2015). Organic–inorganic hybrid sol–gel coatings for metal corrosion protection: a review of recent progress. Journal of Coatings Technology and Research, 12, 1-35.
  • Gençer, G. M. (2021). The Importance of Corrosion Protection of Metal-Containing Historical Artifacts and Common Methods Used for Preservation. International Journal of Environment and Geoinformatics, 8(4), 514-520.
  • Hollander, O. and R. C. May (1985). The chemistry of azole copper corrosion inhibitors in cooling waters. Corrosion 41(1), 39-45.
  • Högberg, A. and C. Holtorf (2021). Cultural heritage and the future, Routledge.
  • Ismail, K. M. (2007). Evaluation of cysteine as environmentally friendly corrosion inhibitor for copper in neutral and acidic chloride solutions. Electrochimica Acta, 52(28), 7811-7819.
  • Khan, P. F., Shanthi, V., Babu, R. K., Muralidharan, S., Barik, R. C. (2015). Effect of benzotriazole on corrosion inhibition of copper under flow conditions. Journal of Environmental Chemical Engineering 3(1), 10-19.
  • Koob, S. (2009). Paraloid B-72®: 25 years of use as a consolidant and adhesive for ceramics and glass. Holding it All Together Ancient and Modern Approaches to Joining, Repairs and Consolidation, 113-119.
  • Masi, G., Josse, C., Esvan, J., Chiavari, C., Bernardi, E., Martini, C., Bignozi, C.M., Robbiola, L. (2019). Evaluation of the protectiveness of an organosilane coating on patinated Cu-Si-Mn bronze for contemporary art. Progress in Organic Coatings, 127, 286-299.
  • Mastrangelo, R., Chelazzi, D., Poggi, G., Fratini, E., Pensabene Buemi, L., Petruzzellis, M. L., Baglioni, P. (2020). Twin-chain polymer hydrogels based on poly (vinyl alcohol) as new advanced tool for the cleaning of modern and contemporary art. Proceedings of the National Academy of Sciences, 117(13), 7011-7020.
  • Meng, B., Mueller, U., Garcia, O., Malaga, K. (2014). Performance of a new anti-graffiti agent used for immovable cultural heritage objects. International Journal of Architectural Heritage, 8(6), 820-834.
  • Moffett, D. L. (1996). Wax coatings on ethnographic metal objects: justifications for allowing a tradition to wane. Journal of the american institute for conservation, 35(1), 1-7.
  • Muresan, L., Oniciu, L., Froment, M., & Maurin, G. (1992). Inhibition of lead electrocrystallization by organic additives. Electrochimica acta, 37(12), 2249-2254.
  • Pickard, R. (2001). Policy and law in heritage conservation . Londonand New york, Taylor & Francis. Protection, E. C. (2018). Hybrid Sol-Gel Coatings. Production, Properties, and Applications of High Temperature Coatings, 334.
  • Robinson, W. S. (1982). The corrosion and preservation of ancient metals from marine sites. International Journal of Nautical Archaeology, 11(3): 221-231.
  • Sadat‐Shojai, M., Ershad‐Langroudi, A. (2009). Polymeric coatings for protection of historic monuments: Opportunities and challenges. Journal of Applied Polymer Science, 112(4), 2535-2551.
  • Salzano de Luna, M., Buonocore, G. G., Giuliani, C., Messina, E., Di Carlo, G., Lavorgna, M., Ambrosio, L., Ingo, G. M. (2018). Long‐lasting efficacy of coatings for bronze artwork conservation: the key role of layered double hydroxide nanocarriers in protecting corrosion inhibitors from photodegradation. Angewandte Chemie International Edition, 57(25), 7380-7384.
  • Sesana, E., Gagnon, A. S., Ciantelli, C., Cassar, J., Hughes, J. J. (2021). Climate change impacts on cultural heritage: A literature review. Wiley Interdisciplinary Reviews: Climate Change, 12(4), e710.
  • Sloggett, R. (2022). Conservation skills. Journal of the Institute of Conservation, 45(3), 157-172.
  • Stulik, D. (2004). Solvent gels for the cleaning of works of art: the residue question. Getty Publications.
  • Telegdi, J., Shaban, A., Trif, L. (2017). Microbiologically influenced corrosion (MIC). Trends in oil and gas corrosion research and technologies, 191-214.
  • Wang, T., Wang, J., Wu, Y. (2015). The inhibition effect and mechanism of l-cysteine on the corrosion of bronze covered with a CuCl patina. Corrosion Science, 97, 89-99.
  • Watkinson, D. (2010). 4.43 Preservation of Metallic Cultural Heritage. Corrosion Management, 3307-3340.
  • Winther, T., Bannerman, J., Skogstad, H., Johansson, M. K., Jacobson, K., Samuelsson, J. (2015). Adhesives for adhering polystyrene plastic and their long-term effect. Studies in Conservation, 60(2), 107-120.
  • Wolbers, R. (2000). Cleaning painted surfaces: aqueous methods.
  • Yarime, M., Trencher, G., Mino, T., Scholz, R. W., Olsson, L., Ness, B., Frantzeskaki, N., Rotmans, J. (2012). Establishing sustainability science in higher education institutions: towards an integration of academic development, institutionalization, and stakeholder collaborations. Sustainability Science, 7, 101-113.
  • Yadav, S., Raman, A. P., Singh, M. B., Massey, I., Singh, P., Verma, C., AlFantazi, A. (2024). Green nanoparticles for advanced corrosion protection: Current perspectives and future prospects. Applied Surface Science Advances, 21, 100605.
There are 50 citations in total.

Details

Primary Language English
Subjects Geological Sciences and Engineering (Other)
Journal Section Review Articles
Authors

Emine Kutlu 0000-0003-0211-1006

Muhammad Ali 0000-0002-8565-3136

Project Number -
Early Pub Date August 31, 2024
Publication Date September 28, 2024
Submission Date May 4, 2024
Acceptance Date August 31, 2024
Published in Issue Year 2024 Volume: 11 Issue: 3

Cite

APA Kutlu, E., & Ali, M. (2024). A Review on Conservational Methodologies of Tangible Cultural Artifacts from Environmental Corrosion. International Journal of Environment and Geoinformatics, 11(3), 24-29. https://doi.org/10.30897/ijegeo.1478498