Abstract
The corrosion products usually found on outdoor bronzes are generated by the interaction between the metal alloy and the atmospheric pollutants. To protect the external surface of bronzes, different organic materials (natural or synthetic) can be applied, creating over time a patina consisting of a complex mixture of inorganic and organic degraded components. The correct chemical characterization of patina constituents is fundamental to define the state of conservation of a metal artwork and address proper restoration actions. In this paper, we evaluated the potentialities of near-infrared (NIR) reflectance microscopy (4000–7500 cm−1) as complementary method to mid-infrared (MIR) analyses for the characterization of bronze patinas. Although NIR spectroscopy has been already used in the field of heritage science, its application for the characterization of bronze patinas is almost unexplored. In this paper, several corrosion products usually found on the surface of outdoor bronze sculptures were synthesized, characterized, and submitted to the NIR-MIR total reflection analysis to build up a reference spectral database. We devoted particular attention to the NIR features of copper hydroxychlorides, such as atacamite and paratacamite, which have not been studied in detail up to now. A selection of organic-based formulations, commonly used by restorers to protect the bronze surface against the outdoor aggressive environment, were also considered as references. Successively, NIR-MIR reflectance microscopy was successfully employed for the analysis of patina micro-samples collected from the bronze statues of the Neptune Fountain (sixteenth century) located in Bologna. The obtained results demonstrate the ability of NIR spectroscopy to identify organic and inorganic patina constituents, even in mixtures. In addition, the study can be considered as a proof of concept for the possible future application of the technique for in situ diagnostic campaigns on bronze sculptures.
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References
Bacci M, Baronti S, Casini A, Lotti F, Picollo M, Casazza O (1992) Non-destructive spectroscopic investigations on paintings using optical fibers. Mat Res Soc Symp Proc 267:265–283
Bertolotti G, Bersani D, Lottici PP, Alesiani M, Malcherek T, Schlüter J (2012) Micro-raman study of copper hydroxychlorides and other corrosion products of bronze samples mimicking archaeological coins. Anal Bioanal Chem 402:1451–1457
Buti D, Rosi F, Brunetti BG, Miliani C (2013) In-situ identification of copper-based green pigments on paintings and manuscripts by reflection FTIR. Anal Bioanal Chem 405:2699–2711
Chaffin NC, Griffiths PR (1998) Role of scattering coefficients in extended near-infrared diffuse reflection spectrometry. Appl Spectrosc 52:218–221
Chiavari G, Ferretti S, Galletti GC, Mazzeo R (1991) Analytical pyrolysis as a tool for the characterization of organic substances in artistic and archaeological objects. J Anal Appl Pyrol 20:253–261
Chiavari C, Rahmouni K, Takenouti H, Joiret S, Vermaut P, Robbiola L (2007) Composition and electrochemical properties of natural patinas of outdoor bronze monuments. Electrochim Acta 52:7760–7769
Cicileo GP, Crespo MA, Rosales BM (2004) Comparative study of patinas formed on statuary alloys by means of electrochemical and surface analysis techniques. Corr Sci 46:929–953
Frost RL, Reddy BJ, Wain DL, Martens WN (2007) Identification of the rosasite group minerals—an application of near infrared spectroscopy. Spectrochim Acta Part A 66:1075–1081
Gaydon JW, Glass HJ, Pascoe RD (2009) Method for near infrared sensor-based sorting of a copper ore. J Near Infrared Spec 17:177–194
Griffiths PR, De Haseth JA (2007) Fourier transform infrared spectrometry, 2nd edn. John Wiley & Sons, New York
Guida G, Marabelli M, Mazzeo R, Morigi G (1994) Chemical and physical examination of the bronze sculptures of the fountainof Neptune in relation to the restoration, the identification of the construction technique and previous restoration works. Science and Technology for Cultural Heritage 3:75–88
Hayez V, Guillaume J, Hubin A, Terryn H (2004) Micro-Raman spectroscopy for the study of corrosion products on copper alloys: setting up of a reference database and studying works of art. J Raman Spectrosc 35:732–738
Hayez V, Costa V, Guillaume J, Terryn H, Hubin A (2005) Micro Raman spectroscopy used for the study of corrosion products on copper alloys: study of the chemical composition of artificial patinas used for restoration purposes. Analyst 130:550–556
Hunt GR (1970) Visible and near-infrared spectra of minerals and rocks: I silicate minerals. Mod Geol 1:283–300
Letardi P, Salvadori B, Galeotti M, Cagnini A, Porcinai S, Santagostino Barbone A, Sansonetti A (2016) An in situ multi-analytical approach in the restoration of bronze artefacts. Microchem J 125:151–158
Leygraf C, Wallinder IO, Tidblad J, Graedel T (2000) Atmospheric corrosion. John Wiley & Sons, New York
Liu XD, Meng DD, Zheng XG, Hagihala M, Guo QX (2011) Mid-IR and Raman spectral properties of clinoatacamite-structure basic copper chlorides. Adv Mat Res 146:1202–1205
Marabelli M, Napolitano G (1991) Nuovi sistemi protettivi applicabili su opere o manufatti in bronzo esposti all'aperto. Materiali e strutture 1:51–56
Marabelli M, Mazzeo R, Morigi G (1991) Caratterizzazione dei prodotti di alterazione e della vernice nera dei bronzi della Fontana del Nettuno. OPD/Restauro 3:57–62
Martens W, Frost RL, Kloprogge JT, Williams PA (2003a) Raman spectroscopic study of the basic copper sulphates—implications for copper corrosion and ‘bronze disease’. J Raman Spectrosc 34:145–151
Martens W, Frost RL, Williams P (2003b) Raman and infrared spectroscopic study of the basic copper chloride minerals–implications for the study of the copper and brass corrosion and ‘bronze deseas’. Journal of mineralogy and Geochemistry 178:197–215
Matteini M, Moles A, Lalli C (1984) Infrared spectroscopy: a suitable tool for the characterization of components in bronze patinas. In: Icom 7th triennial meeting. Copenhagen pp 84–22
Mazzeo R (2005) Patine su manufatti metallici In: Le Patine. Genesi, significato, Conservazione, Kermes quaderni, Nardini, Firenze, pp 29–43
Mazzeo R, Joseph E (2007) Attenuated total reflectance microspectroscopy map** for the characterisation of bronze corrosion products. Eur J Mineral 19:363–371
Miliani C, Rosi F, Borgia I, Benedetti P, Brunetti BG, Sgamellotti A (2007a) Fiber-optic fourier transform mid-infrared reflectance spectroscopy: a suitable technique for in situ studies of mural paintings. Appl Spectrosc 61:293–299
Miliani C, Rosi F, Burnstock A, Brunetti BG, Sgamellotti A (2007b) Non-invasive in-situ investigations versus micro-sampling: a comparative study on a Renoirs painting. Appl Phys A Mater Sci Process 89:849–856
Miliani C, Daveri A, Brunetti BG, Sgamellotti A (2008) CO2 entrapment in natural ultramarine blue. Chem Phys Lett 466:148–151
Miliani C, Rosi F, Daveri A, Brunetti BG (2012) Reflection infrared spectroscopy for the non-invasive in situ study of artists’ pigments. Appl Phys A Mater Sci Process 106:295–307
Pitthard V, Stone R, Stanek S, Griesser M, Hanzer H (2011) Organic patinas on renaissance and baroque bronzes–interpretation of compositions of the original patination by using a set of simulated varnished bronze coupons. J Cul Herit 12:44–53
Poli T, Chiantore O, Nervo M, Piccirillo A (2011) Mid-IR fiber-optic reflectance spectroscopy for identifying the finish on wooden furniture. Anal and Bioanal Chem 400:1161–1171
Rama Subba Reddy R, Lakshmi Reddy S, Siva Reddy G, Reddy BJ (2002) Spectral studies of divalent copper in antlerite mineral. Cryst Res Technol 37:485–490
Reddy KM, Jacob AS, Reddy BJ, Reddy YP (1987) Optical absorption spectra of Cu2+ in brochantite. Phys Status Solidi B 139:K146–K150
Rosi F, Daveri A, Doherty B, Nazzareni S, Brunetti BG, Sgamellotti A, Miliani C (2010) On the use of overtone and combination bands for the analysis of the CaSO4–H2O system by mid-infrared reflection spectroscopy. Appl Spectrosc 64:956–963
Rosi F, Daveri A, Moretti P, Brunetti BG, Miliani C (2016) Interpretation of mid and near-infrared reflection properties of synthetic polymer paints for the non-invasive assessment of binding media in twentieth-century pictorial artworks. Microchem J 124:898–908
Sciutto G, Prati S, Bonacini I, Olivieri P, Mazzeo R (2014) FT-NIR microscopy: an advanced spectroscopic approach for the characterisation of paint cross-sections. Microchem J 112:87–96
Scott DA (2002) Copper and bronze in art: corrosion, colorants, conservation. Getty publications, Los Angeles
Secco EA (1988) Spectroscopic properties of SO4 (and OH) in different molecular and crystalline environments. I. Infrared spectra of Cu4(OH)6SO4, Cu4(OH)4OSO4, and Cu3 (OH)4SO4. Can J Chem 66:329–336
Serghini-Idrissi M, Bernard MC, Harrif FZ, Joiret S, Rahmouni K, Srhiri A, Takenouti H, Vivier V, Ziani M (2005) Electrochemical and spectroscopic characterizations of patinas formed on an archaeological bronze coin. Electrochim Acta 50:4699–4709
Sharkey JB, Lewin SZ (1971) Conditions governing the formation of atacamite and paratacamite. The American Mineralogist 56:179–192
Squarcialupi MC, Bernardini GP, Faso V, Atrei A, Rovida G (2002) Characterisation by XPS of the corrosion patina formed on bronze surfaces. J Cult Herit 3:199–204
Sreeramulu P, Reddy KM, Jacob AS, Reddy BJ (1990) UV-VIS, NIR, IR, and EPR spectra of connellite. J Crystallogr Spectrosc Res 20:93–96
Strandberg H (1998) Reactions of copper patina compounds—I. Influence of some air pollutants. Atmosph Environ 32:3511–3520
Tennent NH, Antonio KM (1981) Bronze disease: synthesis and characterisation of botallackite, paratacamite and atacamite by infra-red spectroscopy. In: Icom committee for conservation. 6th triennial meeting. Ottawa, p 11
Vagnini M, Miliani C, Cartechini L, Rocchi P, Brunetti BG, Sgamellotti A (2009) FT-NIR spectroscopy for non-invasive identification of natural polymers and resins in easel paintings. Anal Bioanal Chem 395:2107–2118
Zaffino C, Guglielmi V, Faraone S, Vinaccia A, Bruni S (2015) Exploiting external reflection FTIR spectroscopy for the in-situ identification of pigments and binders in illuminated manuscripts. Brochantite and posnjakite as a case study. Spectrochim Acta A 136:1076–1085
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Catelli, E., Sciutto, G., Prati, S. et al. Characterization of outdoor bronze monument patinas: the potentialities of near-infrared spectroscopic analysis. Environ Sci Pollut Res 25, 24379–24393 (2018). https://doi.org/10.1007/s11356-018-2483-3
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DOI: https://doi.org/10.1007/s11356-018-2483-3