Abstract

In Belém, Brazil, during the 19th century, Portuguese tiles were used for the external facing of sepultures at the Soledade Cemetery. These pieces are fragile because of exposure to the tropical climate and of their location close to the ground. This research aims to obtain subsidies for the restoration of the glazed layer, through hot restoration, to serve as theoretical and technological references for future restoration projects. The samples consisted of fragments of Portuguese historical tiles from the Soledade Cemetery. Restoration was performed by cleaning (both mechanical and chemical ways) and re-firing (1000ºC). Before and after the re-firing, samples were submitted to the analytical technique of X-ray diffraction. The results indicate that the re-firing eliminated defects and pathologies existent in the glaze and caused changes in the mineralogical composition of the ceramics. Used carefully, the hot technique is one of the alternatives to improve durability and protect the Soledade historical tiles.

Keywords:
glazed ceramic tiles; restoration; firing

1. Introduction

Tiles are glazed ceramic pieces, with cultural value, frequently used in architecture. Depending on where they are fixed, tiles may need specific interventions of restoration, which could be performed through either hot or cold restoration. Each one presents positive and negative consequences, depending on the quality of the manufacturing process and environmental conditions to which the restored pieces will be exposed.

A conservation or restoration project must be based on the documentation (register and diagnose of conservation status) and scientific analysis of the material and its alterations (characterization). It should aim to reduce environmental effects, in order to: 1) rescue the aesthetic characteristics and functionality of the object (Fabbri, 2003FABBRI, Bruno. La caratterizzazion dei materiali nel restauro di ceramic invetriata in contest archittetonico. In: ____. El estúdio y la conservacíon de la cerâmica decorada em arquitectura. Roma: ICCROM, 2003. Cap. I, p. 15-21. 164 p.); and 2) promote durability, because the repetition of interventions with short longevity may result in the loss of its original configuration or its essence (Oliveira, 2001OLIVEIRA, M. M. de. Materiais de revestimento aplicados na conservação de azulejos. In: ____. Patrimônio azulejar brasileiro: aspectos históricos e de conservação. Brasil: Monumenta - BID - Ministério da Cultura, 2001. Cap. 11, p. 140-163. 195p.).

In restorative interventions, materials to be used should have characteristics that are similar to the layers they will replace, so, in areas with glaze loss, the material used must be resistant to climatic actions, be impermeable, and adhere well to the ceramic layer (Sanjad, 2009SANJAD, T. A. B. C. Azulejaria histórica em Belém do Pará: contribuição tecnológica para réplicas e restauro. Belém: UFPA/SEDECT, 2009. 109 p.). Hot restoration was studied in various researches (Oliveira, 2001OLIVEIRA, M. M., SANJAD, T. A. B., BASTOS, C. J. P. Biological degradation of glazed ceramic tiles. In: INTERNATIONAL SEMINAR HISTORICAL CONSTRUCTIONS, 2001. Guimarães. Anais... Portugal. 2001, v. 3, p.337-342.; Sanjad, 2002SANJAD, T. A. B. C. Patologias e conservação de azulejos: estudo tecnológico de conservação e restauração com azulejos dos séculos XVI, XVII e XIX pertencentes às cidades de Belém e Salvador. Salvador, UFBA, 2002. 207 p. (Dissertação Mestrado em Arquitetura e Urbanismo).; Burgos, 2003BURGOS, J. A. S. La restauracion de la ceramica vidriad de la Plaza de España, Sevilha. In: ____. El estúdio y la conservacíon de la cerâmica decorada em arquitectura. Roma: ICCROM, 2003. Cap. I, p. 42-47. 164 p.; Schwarz et al., 2003SCHWARZ, H-J., FREYBURG, S., MOTTNER, P., STADLBAUER, E. Conservation and restoration of glazed architectural ceramics in northern Germany. In: ____. El estúdio y la conservacíon de la cerâmica decorada em arquitectura. Roma: ICCROM, 2003. Cap. I, p. 38-41. 164 p.; Leite, 2011LEITE, V. Desenvolvimento de técnica de restauração a quente em azulejos dos séculos XVII, XVIII e XIX. Salvador: UFBA, 2011. 149 p. (Dissertação de Mestrado em Arquitetura e Urbanismo).): 1) to remove dark stains (microorganisms) existent between the glaze and the ceramic; 2) to perform chromatic reintegration in the glazed layer, using glazes similar to the originals. In this kind of procedure, the tiles need to go through a new firing process with appropriate temperatures, respecting the instability gap of the minerals, in order to prevent any harmful alteration. Therefore, due to the recovery of the glazed layer, which provides impermeability to tiles, the process ensures greater durability of the interventions carried out on outdoor pieces (exposed to actions of weathering) (Oliveira, 2001OLIVEIRA, M. M. de. Materiais de revestimento aplicados na conservação de azulejos. In: ____. Patrimônio azulejar brasileiro: aspectos históricos e de conservação. Brasil: Monumenta - BID - Ministério da Cultura, 2001. Cap. 11, p. 140-163. 195p.). It also guarantees the aesthetic compatibility of the intervention and the ancient material (Sanjad, 2009SANJAD, T. A. B. C. Azulejaria histórica em Belém do Pará: contribuição tecnológica para réplicas e restauro. Belém: UFPA/SEDECT, 2009. 109 p.).

In Belém, tiles were frequently used to coat the façades of historic buildings, especially during the 19th century. In this period, the use of tiles in the mortuary architecture of Nossa Senhora da Soledade Cemetery stands out as the external coating of sepultures. Despite the city's vast heritage of tiles, only a few tiled façades have been restored. Moreover, inappropriate procedures for tiles used for external facing were applied in the interventions, due to low durability when exposed to weathering (Sanjad, 2007SANJAD, T. A. B. C. Intemperismo tropical em fachadas azulejadas de edificações históricas de Belém do Pará. Belém: UFPA, 2007. 289 p. (Tese de Doutorado em Ciências - Geologia e Geoquímica).).

At this monumental romantic cemetery, built in 1850, it is possible to find Portuguese tiles decorated by the stamp technique. They are important components in the heritage of Brazilian tiles, due to their decorative patterns (artistic value) (Riegl, 2006RIEGL, A. O culto aos monumentos modernos: sua essência e sua gênese. Goiânia: UCG, 2006. 120 p. (Tradução Elaine Ribeiro Peixoto e Albertina Vicentine).) and they are inserted into a context in which the laying of tiles on cemetery structures was rare, even in Europe (Queiroz, 2012QUEIROZ, F. Azulejaria romântica nos cemitérios portugueses (1850-1880). In: CONGRESSO INTERNACIONAL AZULEJAR, 2012. Aveiro e Ovar. Anais... Portugal, 2012. v.1, p.1-10) (historical value) (Riegl, 2006). The tiles from the Soledade are fragile because of exposure to the tropical climate, human actions and their location close to ground. They are favorable to the development of pathologies, such as glaze loss and proliferation of microorganisms between the glazed and ceramic layers, which accelerates deterioration.

Due to the historical and artistic importance of this material, a restorative intervention is required. The restoration must aim to extend the lifetime of the original material and to prevent them from being replaced by replicas.

The aim of this research is to obtain subsidies for the restoration of glazed layers, through hot restoration, to serve as a theoretical and technological reference for future restoration projects.

2. Materials and methods

2.1 Sampling

The samples consisted in fragments of Portuguese historical tiles, decorated by the stamp technique, collected from eight different graves of Soledade Cemetery (Figure 1). The collection was authorized by the National Historic and Artistic Heritage Institute - IPHAN (Instituto de Patrimônio Histórico e Artístico Nacional). The samples were taken from areas where extraction was easy, in which the pieces were already fractured and had weak adhesion to the support, in order not to compromise the artistic unity of the graves and avoid promoting new damages.

2.2 Restoratives procedures

The tiles were cleaned mechanically, using a surgical scalpel, and chemically, with a wash of distilled water and acetone application on decorative layers. The fragments were dried for 24 hours at 100ºC in a Quimis, model Q317M-32 kiln, to remove moisture.

The re-firing was performed at 1000ºC, during thirty minutes, in a Quimis, model G318M24 Quimis muffle oven. The use of elevated temperature, near the temperature of tile manufacturing, was chosen in order to: remove dark stains (bio-colonization) that existed between the glaze and ceramic layers; restore adhesion of the glaze to the ceramic; and recast the vitrified layer in order to correct defects like vacuoles, microcracks and fissures. In samples with problems originating from this re-firing, a second re-firing was performed under the same conditions as the first.

Before and after the hot restoration, the mineralogical composition of the tiles was determined by Powder X-ray Diffraction Analysis, using a PANalytical X'Pert PRO MPD (PW3040/60, q/q) diffractometer with a ceramic X-ray tube (Cu anode, Ka1= 1.540598 Å), Kb Ni filter, and an X'celerator PSD (Position-Sensitive Detector), belonging to the Laboratory of Mineral Characterization (LCM), at the Institute of Geosciences, UFPA. Instrumental conditions used are as follows: scan range from 5 to 100º, y, tube power of 40 kV and 30 mA, step size of 0.02º, time/step of 60 s, divergence slit of 1/8º, anti-scattering slit of 1/4º, mask of 10 mm, and sample spinning with a rotation time of 1.0 s.

3. Results

3.1 Hot restoration of tiles

The cleaning of the tile samples removed the dirt deposits and superficial bio-colonization. The first re-firing eliminated or softened the defects and pathologies that exist in the glaze (Figure 2). The pieces presented brighter and more highlighted colors. The adherence of the glaze to the ceramic, previously weakened mainly due to dark stains (microorganisms) in the interface zone between the layers (Oliveira, 2001OLIVEIRA, M. M., SANJAD, T. A. B., BASTOS, C. J. P. Biological degradation of glazed ceramic tiles. In: INTERNATIONAL SEMINAR HISTORICAL CONSTRUCTIONS, 2001. Guimarães. Anais... Portugal. 2001, v. 3, p.337-342.), was restored and this bio-colonization was also removed during the heat treatment.

It was observed that some fragments developed new problems. In the vitrified layer, the formation of air bubbles was verified in the AZ.H7-01, AZ.I14-02 and AZ.O12-01 samples. Regarding the ceramics, there was the appearance of deep fissures and a change in color and texture in the AZ.N33-01 fragment. In contrast, in the second re-firing, performed in samples with defects in the vitrified layer, the glazes were made uniform with softening and/or disappearance of bubbles (Figure 3).

The X-ray diffraction analyses show that before the firing, the samples basically contained: quartz, gehlenite, calcite, and Ca-bearing minerals such as wollastonite (AZ.C11, AZ.H7, AZ.M5, and AZ.N33 AZ.O12) and anorthite (AZ.I14) and Ca,Mg-minerals as diopside (AZ.I14, AZ.M18, AZ.P3). After the firing, the calcite, originally present in most of the samples, disappeared. There was formation of diopside in AZ.B25, AZ.C11 and AZ.M5; and anorthite in AZ.C11 (Figure 4).

4. Discussions

Based on the results, it was possible to improve the visual aspects and fix manufacturing defects and alterations due to re-vitrification of the decorative layer, since the temperature reached was sufficient for a new fusion of the materials. The dark stains of bio-colonization in the interface area between the layers (Oliveira et al., 2001OLIVEIRA, M. M., SANJAD, T. A. B., BASTOS, C. J. P. Biological degradation of glazed ceramic tiles. In: INTERNATIONAL SEMINAR HISTORICAL CONSTRUCTIONS, 2001. Guimarães. Anais... Portugal. 2001, v. 3, p.337-342.) were also removed during heat treatment due to the carbonization of the organic material (Sanjad, 2002SANJAD, T. A. B. C. Patologias e conservação de azulejos: estudo tecnológico de conservação e restauração com azulejos dos séculos XVI, XVII e XIX pertencentes às cidades de Belém e Salvador. Salvador, UFBA, 2002. 207 p. (Dissertação Mestrado em Arquitetura e Urbanismo).).

The air bubbles in the glaze of some samples were possibly caused by the release of carbon dioxide after the breaking down of the calcium carbonate structure and/or of organic matter in the ceramic (Costa et al., 2013COSTA, M. L., SANJAD, T. A. B. C., PAIVA, R. S. The mineralogy and chemistry of the German and Portuguese tiles used to face a historic building in the Amazon region and their natural susceptibility to tropical weathering. Acta Amazonica (Impresso), v. 43, n. 3, p. 323-330, 2013.). In the second new firing, these defects in the vitrified layers were minimized, probably due to: 1) re-accommodation of the glaze, which with the high temperature passed to liquid state, causing a re-vitrification; 2) the low release of CO₂, since most of the organic particles were eliminated from the ceramic during the first new firing and due to inexistence (or low quantity) of carbon dioxide.

As for the change in the ceramic of the AZ.33-01 sample, this result shows certain fragility due to the alterations suffered by the tile, which are probably related to the area of the grave in which the tile was inserted. Since this tile was part of a panel fixed on the lateral of the N33 grave, in direct contact with the ground, the piece may have absorbed too much humidity, as well as organic and inorganic components.

Despite giving durability to the elements exposed to weathering and the use of materials and techniques similar to the original, it is observed that the firing treatments can also present risks to the material according to its chemical and mineralogical composition or level of alteration. Tests should be conducted on small fragments prior to a mass intervention.

From the point of view of the material safeguarding, the hot restoration results are contributive. However, this procedure has some conceptual limitations, based on classic restoration theories. Brandi (2008)BRANDI, C. Teoria da restauração. (3.ed.). Cotia, SP: Ateliê Editorial, 2008. 149 p. (Tradução Beatriz Mugayar Kühl)., defines that "restoration must aim to reestablish the potential unity of a work of art , as long as is possible without producing an artistic or historical forgery, and without erasing every trace of the passage of time on the artwork", and "restoration must be reversible". Hot restoration goes against some of these principles because it is irreversible; can compromise the marks of time in the original piece, due to the new fusion of the glaze; and may change the composition of the original material. Despite this, contemporaneous restoration theories are more flexible about these concepts, and seen as subjective, since they depend on a point of view.

According to Viñas (2004), restoration is not a neutral activity, since it involves a series of technical and ideological elections. In some cases, the conditions of the artifact may require the sacrifice of part of the material's consistency in order to safeguard it. Due to the fact that the work of art, in tiles, is present in the painting, the preservation of the glazed surface is a priority (Oliveira, 2001OLIVEIRA, M. M., SANJAD, T. A. B., BASTOS, C. J. P. Biological degradation of glazed ceramic tiles. In: INTERNATIONAL SEMINAR HISTORICAL CONSTRUCTIONS, 2001. Guimarães. Anais... Portugal. 2001, v. 3, p.337-342.), which was secured through the hot restoration.

Changes in the mineralogical composition of the ceramics occurred due to the mineral transformations that may happen because of re-firing temperature. re-firing time, and rate of temperature increase (Riccardi et al., 1999RICCARDI, M. P., MESSIGA, B., DUMINUCO, P. An approach to the dynamics of clay firing. Applied Clay Science, v. 15, p. 393-409, 1999.; Cultrone et al., 2004CULTRONE, G., SEBASTIN, E., ELERT, K., TORRE, M.J., CAZALLA, O., RODRIGUEZ-NAVARRO, C. Influence of mineralogy and firing temperature on the porosity of bricks. Journal of the European Ceramic Society, v. 24, p. 547-564, 2004.; Vaz et al., 2008VAZ, M. F., PIRES, J., CARVALHO, A. P. Effect of the impregnation treatment with Paraloid B-72 on the properties of old Portuguese ceramic tiles. Journal of Cultural Heritage, v. 9, p. 269-276, 2008.; Cultorne and Madkur, 2013CULTRONE, G., MADKOUR, F. Evaluation of the effectiveness of treatment products in improving the quality of ceramics used in new and historical buildings. Journal of Cultural Heritage, v. 14, p. 304-310, 2013.). It is very likely that the calcite, a mineral with fusion temperature of about 900 ºC, present in most samples before re-firing, was derived from the mortar (Sanjad et al., 2004SANJAD, T. A. B. C., ANGÉLICA, R. S., OLIVEIRA, M. M. de, COSTA, M. L. da. Caracterização mineralógica de azulejos de Salvador e Belém dos séculos XVI, XVII e XIX. REM - Revista Escola de Minas, v.57, n.4, p. 255-260, 2004.; Costa et al., 2013COSTA, M. L., SANJAD, T. A. B. C., PAIVA, R. S. The mineralogy and chemistry of the German and Portuguese tiles used to face a historic building in the Amazon region and their natural susceptibility to tropical weathering. Acta Amazonica (Impresso), v. 43, n. 3, p. 323-330, 2013.), since the tiles had minerals in their composition such as gehlenite, formed at about 1000ºC (Sanjad et al., 2004SANJAD, T. A. B. C., ANGÉLICA, R. S., OLIVEIRA, M. M. de, COSTA, M. L. da. Caracterização mineralógica de azulejos de Salvador e Belém dos séculos XVI, XVII e XIX. REM - Revista Escola de Minas, v.57, n.4, p. 255-260, 2004.). Thus, the calcite disappeared after the re-firing at 1000ºC. According to the re-firing temperatures, it is possible that silica reacts with: 1) calcium compounds that originate wollastonite; 2) calcium and magnesium compounds which originate diopside; and 3) gehlenite and aluminum phases, resulting in anorthite (Riccardi et al., 1999RICCARDI, M. P., MESSIGA, B., DUMINUCO, P. An approach to the dynamics of clay firing. Applied Clay Science, v. 15, p. 393-409, 1999.; López-Acre et al., 2003LÓPEZ-ARCE, P, GARCIA-GUINEA, J., GRACIA, M., OBIS, J. Bricks in historical buildings of Toledo City: characterisation and restoration. Materials Characterization, v. 50, n. 1, p. 59-68, 2003.; Tratoré and Kabré, 2003TRAORÉ, K., KABRÉ, T.S., BLANCHARTB, P. Gehlenite and anorthite crystallisation from kaolinite and calcite mix. Ceramics International, v. 29, p. 377-383, 2003.; Sanjad et al., 2004SANJAD, T. A. B. C., ANGÉLICA, R. S., OLIVEIRA, M. M. de, COSTA, M. L. da. Caracterização mineralógica de azulejos de Salvador e Belém dos séculos XVI, XVII e XIX. REM - Revista Escola de Minas, v.57, n.4, p. 255-260, 2004.; Koch, 2008KOCH, L.D ., WALL, D. de. Raman analysis of ancient pigments on a tile from the Citadel of Algiers. Spectrochimica Acta Part A, v. 71, n. 4, p. 1348-1354, 2008.).

5. Conclusions

Due to differences between the various types of tiles, such as their country of origin, fabrication techniques, where they were placed, and deterioration level, it is important that the tiles be scientifically analyzed before performing hot restorative intervention. Otherwise, the restoration may compromise the integrity of the piece, causing irreversible damages.

Used carefully, the hot technique is one of the alternatives to improve durability and protect the heritage of the Soledade tiles and other external coating tiles in the same deterioration situation, mainly concerning the re-vitrification of the decorative layer. However, it is necessary to evaluate the kind of alteration before submitting the historic tiles to this restorative intervention, because of its risks.

Acknowledgements

We are grateful to CAPES for the scholarships to the first author, CNPq for the financial support of research projects to the second author (Process 552690/2011-2 and 484400/2011-8), and PIBIC/UFPA for the scholarships to the third author. We also thank IPHAN/PA, FUMBEL and SEURB, for permission to work at the Soledade Cemetery; LCM, Geosciences Institute at UFPA, for the X-ray analysis.

References

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