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Characterization of copper-based pigment preparation and alteration products

Published online by Cambridge University Press:  14 January 2018

Marcie B. Wiggins ,
Jocelyn Alcántara-García  and
Karl S. Booksh
Marcie B. Wiggins
Affiliation:
Department of Chemistry & Biochemistry, University of Delaware, Newark, DE19716
Jocelyn Alcántara-García*
Affiliation:
Department of Art Conservation, University of Delaware, Newark, DE19716
Karl S. Booksh
Affiliation:
Department of Chemistry & Biochemistry, University of Delaware, Newark, DE19716
*
*(Email: joceag@scholarone.com)
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Abstract

Copper-based pigments are common in works of art that show signs of decay on green and blue areas and are frequently associated with the degradation of organic substrates and/or media (drying oils, cellulose, etc.). The exact causes of degradation remain unknown. This prompted us to study possible starting and degradation products of one especially reactive copper pigment, verdigris (copper acetate), as well as pigments of the same family (salt and soap greens). Preparation of pigments using historical methods was followed by spectroscopic and crystallographic characterization using Fourier-transform infrared (FTIR) spectroscopy, X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS). Synthesis of verdigris and verdigris-like pigments resulted in a mixture of starting polymorphs of verdigris, including neutral and basic verdigris. With accelerated aging, pigments degraded to a polymorph of basic verdigris when not affected by organic media, whereas pigments on cellulosic substrates showed oxidized copper species. With this study, we are beginning to understand verdigris starting materials and highlight the complex interactions between pigments and substrates that influence pigment degradation pathways.

Keywords

artinfrared (IR) spectroscopyx-ray diffraction (XRD)x-ray photoelectron spectroscopy (XPS)
Type
Articles
Information
MRS Advances , Volume 2 , Issue 63: International Materials Research Congress XXVI , 2017 , pp. 3973 - 3981
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Copyright
Copyright © Materials Research Society 2018 

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References

References:

Aliatis, I., Bersani, D., Campani, E., Casoli, A., Lottici, P. P., Mantovan, S., Marino, I.-G. and Ospitali, F., Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy 73 (3), 532538 (2009).CrossRefGoogle Scholar
Scott, D. A., Copper and Bronze in Art: Corrosion, Colorants, Conservation. (Getty Conservation Institute, Los Angeles, 2002), p. 270294.Google Scholar
Cavaleri, T., Buscaglia, P., Migliorini, S., Nervo, M., Piccablotto, G., Piccirillo, A., Pisani, M., Puglisi, D., Vaudan, D. and Zucco, M., Applied Physics A 123 (6), 419 (2017).CrossRefGoogle Scholar
Banik, G., Restaurator 10 (2), 6173 (1989).Google Scholar
Ricciardi, P., Pallipurath, A. and Rose, K., Analytical Methods 5 (16), 38193824 (2013).CrossRefGoogle Scholar
Benetti, F., Perra, G., Damiani, D., Atrei, A. and Marchettini, N., International Journal of Mass Spectrometry 392, 111117 (2015).CrossRefGoogle Scholar
Banik, G., Stachelberger, H., Mairinger, F., Vendl, A. and Ponahlo, J., Microchimica Acta 75 (1), 4955 (1981).Google Scholar
De la Roja, J. M., San Andrés, M., Cubino, N. S. and Santos-Gómez, S., Color Research & Application 32 (5), 414423 (2007).CrossRefGoogle Scholar
Thompson, D. V., The Materials and Techniques of Medieval Painting. (Dover Publications, New York, 1956), p. 163169.Google Scholar
San Andrés, M., de la Roja, J. M., Baonza, V. G. and Sancho, N., Journal of Raman Spectroscopy 41 (11), 14681476 (2010).Google Scholar
Pliny, H. Rackham, Jones, W. H. S. and Eicholz, D. E., Natural history, Volume IX: Book 3-35. (Harvard University Press; W. Heinemann, Cambridge; London, 1979), p. p. 209215.Google Scholar
Gunn, M., Chottard, G., Rivière, E., Girerd, J.-J. and Chottard, J.-C., Studies in Conservation 47 (1), 1223 (2002).CrossRefGoogle Scholar
Scott, D. A., Copper and Bronze in Art: Corrosion, Colorants, Conservation. (Getty Conservation Institute, Los Angeles, 2002), p. 134139.Google Scholar
Phanstiel, O., Dueno, E. and Wang, Q. X., Journal of Chemical Education 75 (5), 612 (1998).Google Scholar
Prati, S., Bonacini, I., Sciutto, G., Genty-Vincent, A., Cotte, M., Eveno, M., Menu, M. and Mazzeo, R., Applied Physics A 122 (1), 10 (2015).Google Scholar
Salvadó, N., Butí, S., Cotte, M., Cinque, G. and Pradell, T., Applied Physics A 111(1), 4757 (2013).Google Scholar
Seah, M. P., Surface and Interface Analysis 2 (6), 222239 (1980).Google Scholar
Kolar, J., Malešič, J., Kočar, D., Strlič, M., De Bruin, G. and Koleša, D., Polymer Degradation and Stability 97(11), 22122216 (2012).Google Scholar
Strlič, M., Kolar, J. and Pihlar, B., Polymer Degradation and Stability 73 (3), 535539 (2001).CrossRefGoogle Scholar
Robinet, L. and Corbeil-a, M.-C., Studies in Conservation 48 (1), 2340 (2003).CrossRefGoogle Scholar
Scott, D. A., Studies in Conservation 45 (1), 3953 (2000).Google Scholar
Naumova, M. M. and Pisareva, S. A., Studies in Conservation 39 (4), 277283 (1994).Google Scholar
Richardin, P., Mazel, V., Walter, P., Laprévote, O. and Brunelle, A., Journal of The American Society for Mass Spectrometry 22 (10), 17291736 (2011).CrossRefGoogle Scholar
Pollard, A. M., Thomas, R. G. and Williams, P. A., Mineralogical magazine 53 (373), 557563 (1989).CrossRefGoogle Scholar
Pierson, J. F., Thobor-Keck, A. and Billard, A., Applied Surface Science 210 (3), 359367 (2003).CrossRefGoogle Scholar
Kolar, J. and Strlič, M., presented at the The Iron Gall Ink Meeting, Newcastle upon Tyne, 2000 (unpublished).Google Scholar
Moulder, J. F., Chastain, J. and King, R. C., Handbook of X-ray Photoelectron Spectroscopy : a Reference Book of Standard Spectra for Identification and Interpretation of XPS Data. (Physical Electronics, Eden Prairie, Minn., 1995), p. 8687.Google Scholar
Strlic, M., Kolar, J. and Pihlar, B., Acta chimica slovenica 46, 555566 (1999).Google Scholar
Goldstein, S., Meyerstein, D. and Czapski, G., Free Radical Biology and Medicine 15 (4), 435445 (1993).Google Scholar
Jančovičová, V., Čeppan, M., Havlínová, B., Reháková, M. and Jakubíková, Z., Chemical Papers 61 (5), 391397 (2007).Google Scholar