1. Introduction
A nationwide project is being carried out in Slovenia, re-evaluating the already known mediaeval mural paintings studied by the previous generations of art historians [
1,
2] (with additional bibliography), and the new findings that emerged in the past few decades. The important new addition to such art historical studies is a systematic interdisciplinary approach, enriching stylistic and historical knowledge with information offered by natural sciences. The investigation of painting supports, pigments, techniques, and artistic procedures are carried out with different analytical techniques. Due to extremely rich mural painting heritage in Slovenia, the first part of this national project entitled
Transformations—from Material to Virtual. Digital Corpus of Mural Painting—New Dimensions of Medieval Art Research in Slovenia is limited to murals from around 1220–1230 (the oldest known paintings) until around 1380. Among these, over 70 localities have been studied. Several mural cycles attract our attention, showing wide areas of darkened colours, which generally indicate degradation of lead, copper, or mercury-based pigments [
3,
4]. One of them especially stands out, being almost totally black, with some rests of greenish-bluish and red areas (
Figure 1). There are no other similar cases found in the entire country.
The mural was discovered under a whitewash layer during restoration works in 1976–1978 [
5,
6] in the left corner of the main nave in St. Jacob church in Ormož, in northeastern Slovenia. The first church in Romanesque style was probably built around 1200 [
6] when this area was taken from Hungarians by Frederic of Ptuj (Pettau) with the help of the German Order of Knighthood. The land around Ormož and Velika Nedelja was added to Styra and therefore, the church, donated to the German Order, fell under the jurisdiction of the Archdiocese in Salzburg. The first documentation regarding the building only dates from 127; between 1270–1280 it must have been enlarged and remodelled in a gothic style, under the German Order’s patronage. By then, it was probably elevated to a parish church, while Ormož received its market rights around 1293 and its city rights in 1331, indicating its historical importance. The next larger architectonical adaptation must have happened between 1354 and 1375 when the northern chapel was added. In 1354, a daily early mass was established by Klara, countess of Gorizia, while in 1376, the St. Catherine altar is mentioned. The art historians consider these dates as the possible time span for the church remodelling [
6,
7]. Perhaps this is the time when the mentioned mural paintings were painted, according to their elegant, predominantly linear style.
The church went through several architectonical and painting remodels throughout the next centuries, becoming a large baroque building. It is worth mentioning that the enlargement of the Romanesque choir to a large gothic rib-vaulted presbytery occurred in the beginning of the 15th century, where, according to some headstones, the most important building workshop at the time, from Ptujska Gora, was working on this assignment [
6,
7]. This is an important fact, showing that the best artists were contracted for the construction and decoration of this church. Through centuries, the city and the church suffered several attacks and fires, and the interior of the church was repainted several times, covering older paintings.
The fragmentary preserved murals, presented in this research, formed part of a side altar, but there is no information about it. In 1376, an altar consecrated to St. Catherine is documented, but its description and location are unknown [
6]. Furthermore, rests of a stone-carved gothic canopy altar were found on the triumphal wall [
5,
6,
7]; one of these two altars was probably linked to these paintings. On the lower band of the triumphal nave wall, four female saints are depicted, each one in an illusionist niche with a semicircular arche, supported by thin columns. Through their attributes, two of them can be identified as Saint Margarete and Saint Agnes, while the other two are not sufficiently conserved for their recognition. On the upper band, a part of the Adoration of the Magi can be recognised. The oldest king is kneeling in front of the Virgin with Child, while in a rocky landscape behind him, two horses and a standing male figure in red (the younger king?) are presented (
Figure 1b). On the northern wall, a fragment of a man turned backwards on a horse can still be deciphered (
Figure 1a). It probably represents a scene from St. Martin’s legend representing the saint sharing his coat with a beggar. Despite the bad conservation and colour changes, it reveals a highly skilled artist [
2,
8]. His style is fairly elegant, expressed through thin figures. Four female saints are characterised with long wavy hair falling down their shoulders, while their torsos are slightly inclined backwards; the St. Martin’s figure shows a certain elegance as well, pointing towards the time around 1350–1370. We can observe a predominantly linear style before the incoming Italian influence in the last quarter of the 14th century. This is also supported by a typical 14th century bordure under the female saints, composed of triangles with acanthus leaves [
1,
2]. The author is anonymous, as are most of the artists in 14th century Slovenia; however, some stylistic and iconographic similarities can be drawn from several murals in Styria and Carinthia, namely in the churches of Oberzeiring, Deinsberg, and Lind [
8].
It is important to mention that these murals were covered several times with newer layers of mural painting, as stated in the conservation report from 1977: “On the northern wall several paintings were observed. Most of them were conserved on the northern part of the triumphal wall, where also parts of the canopy altar were discovered” [
5]. According to art historical studies, around 1400, the entire church was repainted. Only some fragments remain, and it is not clear whether the new layer covered the older 14th century murals nor if they were already altered by then. Furthermore, the triumphal wall was overpainted in the first half of the 16th century with figures of several saints, painted on a thin plaster. These were detached during the intervention works and transported to the restoration workshop of the Institute for Protection of Cultural Heritage in Maribor, Slovenia. Other paintings that cover the north, south, and triumphal walls of the nave can be dated from the 17th century, while in 1873 the local painter Jakob Brollo painted the entire interior. His paintings were removed in the 1970s due to their bad conservation state; only three parts of the detached Last Supper are exposed today in the presbytery [
5,
6].
The principal aim of this research was to find out what happened to the 14th century murals as well as why and when they turned black. For this purpose, besides the stylistic and historic re-evaluation, a material analysis was carried out. Samples of plaster, pigments, and paint layers were extracted in order to: (a) offer scientifically based information on materials (plaster, pigments, binders) and painting techniques (a fresco, a secco, lime, or mixed); (b) to study painting procedures (incisions, pouncing, preparatory drawings, underpaintings, colour modelling) applied by the artist; and (c) to understand the pigment changes.
2. Materials and Methods
The blackened mural paintings from 1350 to 1370 were first studied in situ by the naked eye and with the help of an external light source: a small hand-held lamp. Applied at different inclinations (raking light), it is possible to discern more clearly incisions and pouncing, surface imperfections, colour layer detachments, joints between giornatas, and the possible use of limewash. By this first visual exam, preparatory drawings, basic colour layers, and modelling were also studied. Next, from the areas of specific interest and where the state of the painting allowed it, tiny samples of plaster and colour layers were carefully extracted and documented (
Figure 2). Altogether, 14 samples were taken. Among them, there are eight samples as follows: a very dark brownish colour layer (sample numbers ORM 2–6, 8, 10, and 12), three turquoise layers (ORM 1, 7, and 13), samples which are difficult to distinguish whether they are blue or green, one green (ORM 11), and one light pink (ORM 9). The last one (ORM 14) turned out to be just a sample of a brick in the wall; therefore, it was not analysed. Most of the colour layer samples were prepared as cross sections, embedded in epoxy resin, and studied under an optical microscope. Next, selected cross sections were analysed by Raman spectroscopy, while raw samples were analysed by Fourier transform infrared (FTIR) spectroscopy and Scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDS). A plaster from the sample ORM 9 (the one that contained the most plaster among all the samples) was separated from the colour layers, ground, and studied with X-ray diffraction (XRD).
Cross sections were analysed by an Olympus BX-60 microscope coupled to an Olympus SC50 digital camera, at 50× to 200× magnifications in reflected mode. Visible (VIS) and ultraviolet (UV) light were used on all samples. Plaster composition, colour layers and their sequence, and basic pigment characteristics and their chemical changes were explored with this technique; this also allowed us to discover possible limewash between plaster and/or colour layers.
For Raman analysis carried out on cross sections, a LabRAM HR800 spectrometer (Horiba Jobin-Yvon, Longjumeau, France) was applied, connected to an Olympus BXFM microscope (Tokyo, Japan). A laser with a 785 nm wavelength and a CCD detector were used. Spectra were scanned in the range between 80 cm−1 and 1800 cm−1 at a spectral resolution of 1 cm−1, while time and filter were adapted to each sample point for better results. Calibration was performed using a Si crystal. Non-processed Raman spectra were interpreted by using NGSLabSpec 5.25.15 software (Horiba). Chemical composition of pigments, and in some cases their chemical changes, were identified.
When Raman results were not conclusive, FTIR spectroscopy and SEM-EDS were added to the analytical procedure. For FTIR, raw samples were used. Sample layers were previously separated by scalpel in order to divide paint layers from the mortar and to minimise cross-contamination between different layers. This is important to enhance paint layer signal compared to the mortar one. Samples were compressed in a diamond anvil cell and scanned in transmission mode with the 50 × 50 µm aperture. A FTIR Spectrum 100 spectrometer connected to a Spectrum Spotlight 200 microscope (PerkinElmer, Waltham, MA, USA) was selected. Spectra were scanned using a MCT detector in the range between 4000 cm−1 and 600 cm−1 with a spectral resolution of 4 cm−1; 32 scans were averaged for each spectrum. Spectra were processed by using Spectrum 10.7.2.1630 software (PerkinElmer) and were baseline corrected and normalised before interpretation.
Due to different obstacles, only one raw sample could be analysed by SEM-EDS. The employed equipment is composed of an EVO 25 scanning electron microscope (Zeiss, Barcelona, Spain) with a 65 Ultim Max energy dispersive X-ray spectroscope (Oxford Instruments, Barcelona, Spain). The analysis was carried out at 25 kV of EHT energy and 20 µA current at 8.5 mm working distance. The sample was covered by carbon.
For plaster characterization and the identification of aggregate and binder, X-ray diffraction was applied. Raw plaster sample was ground and sieved through a sieve of 0.063 mm diameter, obtaining a particle size of less than 63 µm. The sample was then placed in a zero diffraction plate. A PANalytical Empyrean X-ray diffractometer (Malvern Panalytical, Malvern, UK) equipped with CuKα radiation and a PIXcel ID detector Malvern Panalytical, Malvern, UK) was used. The samples were measured at 45 kV at a current of 40 mA, in the range of 4° to 70° 2θ and step size of 0.013° 2θ with a scan step time of 68 s. X-ray diffraction patterns were analysed with X’Pert High Score Plus diffraction software v. 4.9 from PANalytical, supported by PAN IICSD v. 3.4 powder diffraction files.
4. Discussion
There are several pigments that can turn black due to different, mostly atmospheric, agents such as alkaline environment, the presence of sulphur, or heat. These are lead pigments (lead white, massicot or litharge, and minium), cinnabar or vermillion, and copper-based pigments such as azurite and malachite [
3,
4]. In the studied paintings in Ormož, the analysis of paint layers confirmed the use of haematite, green earth, malachite (
Figure 8), as well as azurite (
Figure 9). Nevertheless, there are no lead pigments or cinnabar/vermillion; at least, they are not conserved. In several samples of darkened colour, tenorite was identified (
Figure 10) [
11,
12,
14]. Black tenorite (CuO) is generally a degradation product of azurite (2CuCO
3·Cu(OH)
2); however, malachite (CuCO
3·Cu(OH)
2) can also change to tenorite, but normally this occurs after its degradation to paratacamite [
3,
19]. Paratacamite can also be a corrosion product of azurite. Although both copper-based mineral pigments are considered stable—especially malachite—they can suffer chemical changes due to various agents. Malachite can discolour when applied on a fresh plaster due to the alkaline pH of the lime binder. Both pigments can degrade to paratacamite or other copper hydroxychlorides (Cu
2Cl(OH)
3) such as atacamite, clinoatacamite, or botallackite due to the presence of chloride salts in the wall (Cl
− ions present in the plaster, sand, or in the bricks that can react with the basic carbonate). On the other hand, the darkening of tenorite can occur in an alkaline environment (e.g., a fresco painting) and/or due to the exposure to high temperatures (e.g., fire) [
3,
4,
19]. Azurite and malachite can rarely turn bluish-black when exposed to H
2S vapours, especially in frescoes, forming covellite (CuS) [
3]. However, in Ormož, Raman analysis did not find this compound.
The degradation is faster and more common when pigments are ground to fine, small particles, as is the case in this painting, according to cross sections (
Figure 6c,d). These semi-precious expensive minerals were often ground to small grains in order to spend less of it; however, this causes colour intensity loss. For this reason, both pigments were generally underlaid with grey (veneda) or reddish (morello) colour layers to raise the colour intensity [
9,
10], as already suggested by Teophilus in the 12th Century [
20] and by Cennino Cennini in the 15th Century [
21]. In Ormož, we did not find such underlayers and pigments were applied directly on the plaster, as observed on sample cross sections (
Figure 3,
Figure 6,
Figure 7b, and
Figure 11). When applied directly on fresh plaster, the pigment particles must be small for the lime from the plaster to act as a binder. Sometimes, a small amount of an organic binder can be added to the pigment, suggested by FTIR analysis of some samples (
Figure 9b). An experiment by Mattei et al. [
22] researching the different behaviour of small-grained azurite applied a fresco or a secco revealed that the pigment painted on a fresh plaster turned to tenorite within 24 h, while no alteration was observed when painted on a dry surface. There was also no difference observed when azurite was mixed with animal glue as binder. The same experiment also established the transformation to tenorite below the particle size of 25 µm. This degradation does not necessarily occur fast, since it can depend on the progressive alteration of the alkalinity of the plaster, during which the OH
− ions are released. They react with the copper atoms present in the azurite or malachite molecules and first form copper hydroxide, which can transform into water and copper oxide, as pointed out already by Liberti in 1950 [
23].
Therefore, the blackening of copper-based pigments in these murals could have occurred due to their direct application on a fresh plaster, very soon after they were finished. However, it is surprising that in such condition they would not be repaired/repainted soon after; cross sections do not reveal any overpaintings, but they could have been removed together with the upper layers of younger paintings during the intervention works in 1977–1978. An interesting fact mentioned in the restoration report is that Brollo’s paintings from the 19th century were heavily darkened and that the binder was almost entirely degraded [
5,
6]. Perhaps this darkening has the same causing agent as the murals subject to this study and these darkened much later. However, since in this case we have no information on the Brollo’s painting technique, it could be a result of the degradation of one of the organic materials, such as the binder.
It is worth taking into consideration other possible causes for the transformation of copper-based pigments into tenorite, such as the heat. Some experimental studies confirmed that the thermal decomposition of azurite takes place in six stages: at 205 °C, 321 °C, 332 °C, 345 °C, 362 °C, and 842 °C [
24,
25]; this establishes the crucial temperature to be above 300 °C [
25] or, more specifically, at 384 °C [
26]. In order for this to occur on mural paintings, a fire must break out. Historic documents mention several fires in Ormož. The first known fire happened in 1487 when the emperor Frederic III of Habsburg burned down the city during the battle for the land that once belonged to the noble Styria family of Ptuj (Pettau) after the last member, Frederic IX, had died. During this fire, the church was heavily damaged and it is very likely that the mural paintings suffered. Other city fires are documented in 1647, 1704, and 1778, but it is not clear whether the church was also captured by the flames [
6]. In any case, the darkening of Brollo’s paintings that could have been connected to the darkening of the gothic ones could not be a result of a fire since they were made much later. Therefore, their degradation must also have been the result of the interaction with the support or other biological and/or atmospheric agents.
Another cause of darkening could be the alteration of organic materials, such as the binder [
3,
16,
27,
28]. As seen in the Results section, a possible organic binder was suggested by FTIR analyses, however we cannot confirm that it is an original material. According to previous studies, azurite mixed with animal glue changes to green and yellow hues due to conformational structural changes in the binder [
27]. Therefore, glue was probably not the binder in these murals. If azurite is mixed with egg tempera, the pigment–binder interaction lowers the thermal stability of the pigment. When exposed to NO
x/SO
x pollutants, nitrates/nitrites and sulphates can form on the surface of the paint [
25]. However, darkening is most frequently documented as degradation of Cu-containing glazes based on oils, resins, and proteins [
19]. Therefore, the darkening in Ormož could have also occurred—besides the transformation of copper-based pigments to tenorite—because of the alteration of a hypothetical protein binder added to those pigments.
Having all three possibilities in mind, the most probable cause of the darkening is the degradation of basic copper carbonates (azurite and malachite) to tenorite due to their small granulation and their direct contact with the alkaline plaster. However, the fact that they must have been mixed with an organic protein binder, probably egg yolk, could have attributed to this large blackening as well.
Similar blackened colours but limited to selected areas such as the coats of holy figures, haloes, banners, etc, were found on gothic murals in two other locations in northern Slovenia: in the subsidiary church in Ribičje and the subsidiary church of Mary on the Stone in Vuzenica, where some faces also turned black. The analysis of black vestments in Vuzenica revealed a combination of azurite and a lead-based pigment, whereas in Ribičje there were no conclusive results. In Vuzenica, we cannot be sure whether the blackening of the original colour happened due to the degradation of azurite or lead-based pigment, which is more common and happened on the aforementioned faces. The question for all these murals, but especially in Ormož where almost all colours changed to black, remains: how did these paintings look originally? Answering this question seems even more difficult, since we cannot distinguish between the original blue and green areas, while many of the other coloured areas are lost. Our best suggestion is that the black vestments were blue or green, the figures were situated in front of a light blue background, while the landscape must have been in different green hues.
5. Conclusions
Early gothic mural paintings in the nave of St. Jacob´s church in Ormož, Slovenia (1350–1370) are almost totally black. The principal objective of this research was to discover why and when they degraded to this point, as they are a unique case in Slovenia. After a detailed study in situ, several samples, mostly from the blackened areas, were extracted and studied as cross sections under an optical microscope. Most samples were then analysed by Raman and FTIR spectroscopy and one by SEM-EDS to identify pigments and possible chemical changes, while XRD was used for plaster characterization. Analyses identified a plaster made of a high quantity of aggregate—mostly quartz—with some impurities, and a lower quantity of binder (lime), resulting in a relatively bad plaster consistency. As pigments, haematite, green earth, malachite/(para)atacamite, azurite, and tenorite were identified. Furthermore, an organic material was identified by FTIR that could present a binder added to pigments or a consolidant applied in later interventions. Based on these results, we can conclude that the blackening is caused by degradation of copper-based pigments (probably mostly azurite) to tenorite, which can occur in an alkaline environment (e.g., a fresco painting) and/or due to the exposure to high temperatures (e.g., fire). Keeping in mind these pigments’ small granulation and their direct application on fresh plaster without any underpainting, this situation seems to be the most probable cause for the alteration of the copper-based pigments. Although historically, some fires are documented in Ormož as a possible source of high temperatures that could have damaged the paintings. There is also the possibility that the addition of a protein organic binder influenced the final blackening of the paintings. On the other hand, malachite (and perhaps also azurite before turning to tenorite) degraded to copper hydroxychloride, probably paratacamite, as a result of chloride salts in the wall. Similar cases of blackened pigments but limited only to some special areas such as vestments, haloes, or banners were found in two other churches in northern Slovenia, but at least in one of the churches, azurite was mixed with lead-based pigment; its degradation is probably the cause of blackening. Obtained information can help us to visually reconstruct the original aspect of Ormož murals, showing intense blue and green colours. The results are an important part of the larger nationwide project dedicated to the art historical and material re-evaluation of mediaeval murals that is currently going on in Slovenia.