Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-22T22:13:23.983Z Has data issue: false hasContentIssue false

Micro-analytical Evidence of Copper-Based Pigment and Fungal Contamination of Medieval Mural Paintings in Beram, Croatia

Published online by Cambridge University Press:  27 September 2019

Tea Zubin Ferri*
Affiliation:
Materials’ Research Centre of the Istrian County – METRIS, Zagrebačka 30, 52100 Pula, Croatia
Emina Pustijanac
Affiliation:
Department for Natural and Health Sciences, Juraj Dobrila University of Pula, Zagrebačka 30, 52100 Pula, Croatia
Ines Kovačić
Affiliation:
Department for Natural and Health Sciences, Juraj Dobrila University of Pula, Zagrebačka 30, 52100 Pula, Croatia
Josipa Bilić
Affiliation:
Materials’ Research Centre of the Istrian County – METRIS, Zagrebačka 30, 52100 Pula, Croatia
*
*Author for correspondence: Tea Zubin Ferri, E-mail: [email protected]
Get access

Abstract

The aim of the present study was to map the painting materials, degradation processes, and biological features present on the mural painting in the church of St. Mary in Beram (Croatia) to study their possible interaction and produce information helping the preservation of this valuable painting. The research was conducted on micro samples of painting materials taken from different sites along the painting and the characterization of the present fungal species was carried out. The painting samples, together with observable patinas and degradation products, were studied by optical microscopy (OM), scanning electron microscopy, energy-dispersive spectroscopy (SEM/EDS), Fourier-Transform Infrared spectroscopy, and powder X-ray diffraction. Fungal diversity was studied using cultivation methods followed by OM and SEM analyses in addition to molecular analysis. The results contribute to the characterization of the original painting materials, successively added materials and occurred interventions, to the understanding of degradation progressions and fungal biotransformation processes. A mineral, cumengite, a copper-based pigment extremely rarely used in art, was found. Its occurrence together with barium sulfate, gypsum, and calcium oxalate possibly produced by microbiological activity was studied and information was added regarding the composition of painting materials in St. Mary church mural cycle.

Type
Micrographia
Copyright
Copyright © Microscopy Society of America 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ajo, D, Casellato, U & Vigato, PA (2004). Ciro Ferri's frescoes: A study of painting materials and technique by SEM-EDS microscopy, X-ray diffraction, micro FT-IR and photoluminescence spectroscopy. J Cult Herit 5, 333348.Google Scholar
Aliatis, I, Bersani, D, Campani, E, Casoli, A, Lottici, PP, Mantovan, S, Marino, I & Ospitali, F (2009). Green pigments of Pompeian artists’ palette. Spectrochim Acta 73, 532538.Google Scholar
Amoroso, G (2002). Trattato di scienza della conservazione: etica della conservazione, degradi dei monumenti, interventi conservativi, consolidanti e protettivi. Bologna: Alinea editrice.Google Scholar
Barnett, HL & Hunter, BB (1998). Illustrated Genera of Imperfect Fungi, 4th ed. USA: Optics and Laser Technology (Elsevier).Google Scholar
Barnett, JR & Miller, S (2006). Colour and art: A brief history of pigments. Opt Laser Technol 38, 445453.Google Scholar
Bistrović, Ž (2011). Šareni trag istarskih fresaka. Pula: Istarska županija, 6.Google Scholar
Caneva, G, Nugari, MP & Salvadori, O (2007). La biologia vegetale per i beni culturali, vol. 1. Firenze: Nardini Editore.Google Scholar
Cennini, C & Thompson, D.V. (1960). Il libro dell'arte, the craftman's handbook of Cennino Cennini d'Andrea Cennini. New Haven, NY: Dover Publications Inc.Google Scholar
Coccato, A, Moens, L & Vandenabeele, P (2017). On the stability of mediaeval inorganic pigments: A literature review if the effect of climate, material selection, biological activity, analysis and conservation treatments. Herit Sci 5, 125.Google Scholar
Deanović, AB & Kojić-Prodić, B (1977). Paleta majstora Vincent. Bulletin Razreda za likovne umjetnosti Jugoslavenske akademije znanosti i umjetnosti 3, 2136.Google Scholar
de Los Rios, A & Ascaso, C (2005). Contributions of in situ microscopy to the current understanding of stone biodeterioration. Int Microbiol 8, 181188.Google Scholar
Derrick, MR, Stulik, DC & Landry, JM (1999). Infrared Spectroscopy in Conservation Science. Scientific Tools for Conservation. Los Angeles, CA: The Getty Conservation Institute.Google Scholar
Domenech Carbo, MT, Bosch Reig, F, Gimeno Adelantado, JV & Periz Martinez, V (1996). Fourier transform infrared spectroscopy and the analytical study of works of art for purpose of diagnosis and conservation. Anal Chim Acta 330, 207215.Google Scholar
Domenech Carbo, MT, Martinez, P, Gimeno Adelantado, V, Bosch Reig, JV, Moya, F & Moreno, MC (1997). Fourier tranform infrared spectroscopy and the analytical study of sculptures and wall decoration. J Mol Struct 16, 559563.Google Scholar
Eastaugh, E, Walsh, V, Chaplin, T & Siddal, R (2004). The Pigment Compendium. A Dictionary of Historical Pigments. Amsterdam: Elsevier.Google Scholar
Ellis, D, Davis, S, Alexiou, H, Handke, R & Bartley, R. (2007). Descriptions of Medical Fungi, 2nd ed. Adelaide, Australia: University of Adelaide/Mycology Unit, Women's and Children's Hospital, School of Molecular & Biomedical Science.Google Scholar
Eremin, K, Stenger, J, Huang, J, Aspuru-Guzik, A, Betley, T, Vogt, L, Kassal, I, Speakman, S & Khandekar, N (2008). Examinations of pigments on Thai manuscript: the first identification of copper citrate. J Raman Spectroscop 39, 10571065.Google Scholar
Feller, LR (1986). Artists’ Pigments – A Handbook of Their History and Characteristics, vol.1, 2nd ed. Oxford: Oxford University Press.Google Scholar
Fučić, B (1963). Znanstveni referati održani na svečanoj proslavi povodom 500-godišnjice dovršenja opusa zidnih slika signiranih godine 1474. po domaćem majstoru Vincentu iz Kastva u gotičkoj crkvi Majke Božje na Škrilinah na groblju u Bermu u Istri. Bulletin Razreda za likovne umjetnosti JAZU 3, 4248.Google Scholar
Fučić, B (1992). Vincent iz Kastva, Kršćanska sadašnjost i Istarsko književno društvo, Istarsko književno društvo “Juraj Dobrila”, Zagreb/Pazin, 26.Google Scholar
Gadd, GM, Bahri-Esfahani, J, Li, Q, Rhee, YJ, Wei, Z, Fomina, M & Liang, X (2014). Oxalate production by fungi: Significance in geomycology, biodeterioration and bioremediation. Fung Biol Rev 28, 3655.Google Scholar
Garg, KL, Jain, KK & Mishra, AK (1995). Role of fungi in the deterioration of wall paintings. Sci Total Environ 67, 255271.Google Scholar
Gökmen, V, Serpen, A & Fogliano, V (2009). Direct measurement of the total antioxidant capacity of foods: The ‘QUENCHER'approach. Trends Food Sci Technol 20, 278288.Google Scholar
Gorbushina, AA, Heyrman, J, Dornieden, T, Gonzalez-Delvalle, M, Krumbein, WE, Laiz, L, Petersen, K, Saiz-Jimenez, C & Swings, J (2004). Bacterial and fungal diversity and biodeterioration problems in mural painting environments of St. Martins church (Greene–Kreiensen, Germany). Int Biodet Biodegrad 53, 1324.Google Scholar
Gutarowska, B & Czyżowska, A (2009). The ability of filamentous fungi to produce acids on indoor building materials. Ann Microbiol 59, 807813.Google Scholar
Komes, D, Belščak-Cvitanović, A, Horžić, D, Marković, K & Kovačević Ganić, K (2011). Characterisation of pigments and antioxidant properties of three medicinal plants dried under different drying conditions. Proceedings of the 11th International Congress Engineering and Food, May 22–26, Athens, Greece.Google Scholar
Lee, C, Kim, Y, Nagajyothi, PC, Thammalangsy, S & Goung, SJ (2011). Cultural heritage: A potential pollution source in museum. Environ Sci Pollut Res Int 18, 743755.Google Scholar
Lluveras, A, Boularand, S, Andreotti, A & Vendrell-Saz, M (2010). Degradation of azurite in mural paintings: Distribution of copper carbonate, chlorides and oxalates by SRFTIR. Appl Phys 99, 363375.Google Scholar
Ma, Y, Zhang, H, Du, Y, Tian, T, Xiang, T, Liu, X, Wu, F, An, L, Wang, W, Gu, JD & Feng, H (2015). The community distribution of bacteria and fungi on ancient wall paintings of the Mogao Grottoes. Sci Rep 5, 7752.Google Scholar
Mactaggart, P & Mactaggart, A (1998). A Pigment Microscopist's Notebook, 7th Revision. Chard : Mactaggart.Google Scholar
Mihajlovski, A, Seyer, D, Benamara, H, Bousta, F & Di Martino, P (2015). An overview of techniques for the characterization and quantification of microbial colonization on stone monuments. Ann Microbiol 65, 12431255.Google Scholar
Milanesi, C, Baldi, F, Borin, S, Vignani, R, Ciampolini, F, Faleri, C & Cresti, M (2006). Biodeterioration of a fresco by biofilm forming bacteria. Int Biodeter Biodegr 57, 168173.Google Scholar
Mora, P, Mora, L & Philippot, P (1984). Conservation of Wall Paintings. London: Butterworths/ICCROM.Google Scholar
Mueller, G, Foster, M & Bills, G (2004). Biodiversity of Fungi: Inventory and Monitoring Methods, 1st ed. USA: Elsevier Inc.Google Scholar
Olsen, SL (1988). Application of scanning electron microscopy to archaeology. Adv Electron Electron Phys 71, 357380.Google Scholar
Pepe, O, Sannino, L, Palomba, S, Anastasio, M, Blaiotta, G, Villani, F & Moschetti, G (2010). Heterotrophic microorganisms in deteriorated medieval wall paintings in southern Italian churches. Microbiol Res 165, 2132.Google Scholar
Price, B, Pretzel, B (2000) Infrared and Raman Users Group Spectral Database, The Infrared and Raman Users Group, Philadelphia. Available at: http://www.irug.org/Google Scholar
Purington, N & Watters, M (1991). Study of the materials used by medieval Persian painters. JAIC 30(2), 125144.Google Scholar
Rampazzi, A, Andreotti, A, Bonaduce, I, Colombini, MP, Colombo, C & Toniolo, L (2004). Analytical investigation of calcium oxalate films on marble monuments. Talanta 63, 967977.Google Scholar
Rosado, T, Mirão, J, Gil, M, Candeias, A & Caldeira, AT (2014). Role of microorganisms in mural paintings decay. In Science, Technology and Cultural Heritage, Rogerio-Candelera, MA (Ed.), London: CRC Press/Balkema Taylor & Francis Group, pp. 217222.Google Scholar
Salvado, N, Pradell, T, Pantos, E, Papiz, MZ, Molera, J, Seco, M & Vendrell-Saz, M (2002). Identification of copper-based pigments in Jaume Huguet's Gothic altarpieces by Fourier transform infrared microspectroscopy and synchrotron radiation X-ray diffraction. J Synchrotron Rad 9, 215222.Google Scholar
Schoch, CL, Seifert, KA, Huhndorf, S, Robert, V, Spouge, JL, Levesque, CA, Chen, W & Consortium, FB (2012). Nuclear ribosomal internal transcribed spacer (ITS) region as a universal DNA barcode marker for Fungi. PNAS 109, 62416246.Google Scholar
Sterflinger, K (2010). Fungi: Their role in deterioration of cultural heritage. Fung Biol Rev 24, 4755.Google Scholar
Stevens, FL (1913). The Fungi Which Cause Plant Disease, Copyright The MacMillan Co., Reprinted in 1966. USA: Johnson Reprint Corporation.Google Scholar
Stuart, B (2007). Analytical Techniques in Materials Conservation. Cornwall: John Wiley and Sons.Google Scholar
Švarcova, S, Hradil, D, Hradilova, J, Koči, E & Bezdička, P (2009). Micro-analytical evidence of origin and degradation of copper pigments found in Bohemian Gothic murals. Anal Bioanal Chem 395, 20372050.Google Scholar
Unković, N, Grbić, M, Stupar, M, Savković, Ž, Jelikić, A, Stanojević, D & Vukojević, J (2016). Fungal-induced deterioration of mural paintings: In situ and mock-model microscopy analyses. Microsc Microanal 22, 410421.Google Scholar
Unković, N, Ljaljević Grbić, M, Subaković Simić, G, Stupar, M, Vukojević, J, Jelikić, A & Stanojević, D (2015). Biodeteriogenic and toxigenic agents on 17th century mural paintings and facade of the old church of the Holy Ascension (Veliki Krčimir, Serbia). Indoor Built Environ 25, 826837.Google Scholar
van den Berg, KJ, van Eikema Hommes, M, Groen, K, Boon, J & Berrie, B (2000). On copper green glazes in paintings'. In Art et Chimie: La Couleur: Actes du Congres, Groupy, J & Mohen, P (Eds.), pp. 1823. Paris: CNRS Editions.Google Scholar
van Eikema Hommes, M (2004). Changing Pictures: Discolouration in 15th–17th Century Oil Paintings. London, UK: Archetype Publications. pp. 5189.Google Scholar
Ventosa, A & Nieto, JJ (1995). Biotechnological applications and potentialities of halophilic microorganisms. World J Microbiol Biotechnol 11, 8594.Google Scholar