- Research article
- Open Access
Suitable classification of mortars from ancient Roman and Renaissance frescoes using thermal analysis and chemometrics
© Tomassetti et al.; licensee Springer. 2015
- Received: 15 January 2015
- Accepted: 8 April 2015
- Published: 24 April 2015
Literature on mortars has mainly focused on the identification and characterization of their components in order to assign them to a specific historical period, after accurate classification. For this purpose, different analytical techniques have been proposed. Aim of the present study was to verify whether the combination of thermal analysis and chemometric methods could be used to obtain a fast but correct classification of ancient mortar samples of different ages (Roman era and Renaissance).
Ancient Roman frescoes from Museo Nazionale Romano (Terme di Diocleziano, Rome, Italy) and Renaissance frescoes from Sistine Chapel and Old Vatican Rooms (Vatican City) were analyzed by thermogravimetry (TG) and differential thermal analysis (DTA). Principal Component analysis (PCA) on the main thermal data evidenced the presence of two clusters, ascribable to the two different ages. Inspection of the loadings allowed to interpret the observed differences in terms of the experimental variables.
PCA allowed differentiating the two kinds of mortars (Roman and Renaissance frescoes), and evidenced how the ancient Roman samples are richer in binder (calcium carbonate) and contain less filler (aggregate) than the Renaissance ones. It was also demonstrated how the coupling of thermoanalytical techniques and chemometric processing proves to be particularly advantageous when a rapid and correct differentiation and classification of cultural heritage samples of various kinds or ages has to be carried out.
- Ancient Roman frescoes
- Renaissance frescoes
- Thermal analysis
- Principal component analysis (PCA)
Mortars consist of an intimate mixture of sand or pozzolan, binder and water . Studies on ancient mortars are relatively recent [2-4] and have mainly focused on the identification and characterization of their components in order to assign them to a specific historical period, after accurate classification . More recently, numerous authors have focused specifically on the characterization of mortars. For instance, Duran et al.  have used different experimental techniques (TG, DTA, XRD, FTIR, SEM-EDX, Bernard calcimeter, granulometry, mercury intrusion porosimetry and mechanical strength tests) to characterize mortars taken from the walls of three different buildings of Seville (Spain). On the other hand, Pavia and Caro , on the basis of a detailed petrographic analysis, postulated that the ancient Romans used a pure carbonate rock for lime making. Consequently, Roman mortars were probably made using a non-hydraulic, or feebly hydraulic, lime and their hydraulicity was mainly due to the addition of pozzolans. These claims are in good agreement with the findings of Degryse et al.  who used optical microscopy and XRD analysis to study ancient Roman mortars discovered in southwestern Turkey. They suggested that the best type of mortar to be used for further on-site conservation and restoration consists of a mixture of lime and crushed volcanic sediments or rock, that is, of materials very similar to the original materials used also in many other ancient Roman sites. On the other hand, a particular, but more interesting paper was published by E. Pecchioni et al.  reviewing some examples of ancient mortars used in the Florence area. These authors emphasized how mortars play a central role as supports for frescoes, mural paintings and as the white rendering of Renaissance architecture. Their mineralogical and petrographic study of the mortar’s aggregate revealed how, in this case, sand was used as an aggregate rather than crushed stone. Further, this type of investigation provided information on the stone used to make the lime, as well as on the technology used in the manufacturing phases and in kiln firing, and enabled the binder/aggregate ratio to be evaluated. Other recent studies have focused on the processes of deterioration of mortars and the influence of these alterations on the adjacent materials. In this connection J. Elsen  published a review on microscopic studies of historic mortars. The review was accompanied by an extensive bibliography and postulated that the first step in mortar characterization schemes is optical microscopy to identify aggregates and the various mineral additions, binder type, the binder-related particles, the pore structures and how this technique acts as a valuable aid in the damage diagnosis of degraded historic mortars. Lastly, several instrumental analytical methods were used in recent research to study the composition of ancient Roman mortars and stuccos [10,11], above all for the purpose of identifying any differences in their composition in order to distinguish and accurately classify these two different types of artifacts . On the other hand, Conti et al.  have used different analytical techniques (TG-DSC, XRD, FTIR and SEM-EDX) to characterize mortars from different structures of the archaeological site of Baradello (Italy), in order to define its building chronology.
Over the past few years we have studied and characterized several mortar samples from ancient Roman (2nd Century AD) and Renaissance (16th Century) frescoes [13,14]. On the other hand, recently we showed how thermal analysis, in particular thermogravimetry (TG-DTG), coupled with chemometric methods, can be a valid tool for the characterization and classification of several types of archaeological finds and cultural heritage, e.g. pigments , marbles , pottery , fossil bones , and so on. Therefore, we decided to apply thermogravimetric analysis also to several mortars sampled from different ancient Roman and Renaissance frescoes to determine whether, also in the case of ancient mortars, the simple combination of thermal analysis and chemometric methods could be used to obtain a fast but correct classification of ancient mortar samples of different ages.
Samples from ancient Roman frescoes (2nd century A.D.)
Samples were taken from the “Stazione Termini” frescoes, which are part of the “Piazza dei Cinquecento Complex”.
Specimens taken from Renaissance frescoes
“Il Parnaso”: At the end of 1508 Raffaello was invited to Rome to help in the decoration of the rooms of the new apartments of Julius II and he began the main undertaking of his relatively short life starting in the middle room known as “della Segnatura” . On the wall facing onto the Belvedere courtyard, Raffaello depicted the scene that glorifies poetry, namely “Il Parnaso” (Figure 2b), despite the fact that the irregular surface of the wall must have made it very difficult to achieve a smooth pictorial composition. Raffaello used groups of small trees placed in the background and divided the wall into four parts, arranging the characters into groups linked together by secondary figures, synchronizing the whole with the curve of the arch, which descends beyond the top of the window . During the restoration of the fresco carried out in 1962 it was found that Raffaello, in order to gain extra space, lowered the 15th century window opening, which was originally much higher.
“Stanza di Eliodoro”: the specimen examined consisted of two tiny fragments (glued on pottery support, see Figure 2c) of a fresco located originally in the Room of Heliodorus (Ancient Vatican Rooms), specifically in the zone of the “chiaroscuri”, that is the outer area framing the four large frescoes located in that room.
Main thermogravimetric data
% mass loss (a)
% mass loss (b)
DTA T peak (b)
% mass loss (c)
DTA T peak (c)
Residue at 1000°C
This is therefore probably due to the oxidative breakdown of trace quantities of organic substances. The principal data (mass loss, DTA peak temperatures, final % residues) of the main TG and DTA steps are summarized in Table 1.
Cursory examination of the data reveals that the various step temperatures do not differ appreciably in any of the samples, as is true also for the amount of moisture loss in the first step. However, a much higher mass loss in step three (and, as a consequence, a much smaller residue at 1000°C) is observed in the samples obtained from the Ancient Roman frescoes compared with those of the Renaissance frescoes. This would seem to point to a higher percentage of binder and a smaller percentage of filler in the former than in the latter.
The ancient Roman frescoes studied are currently preserved in the Museo Nazionale Romano (Terme di Diocleziano, Rome, Italy) and denoted as “Termini Station” samples in the present paper, as the site from which they originate is near the present-day Termini Central Railway Station (Rome, Italy). They have been labeled as Ta, Tb, Tc, Td, Te (see examples in Figure 1). The Renaissance fresco samples come from the Sistine Chapel or the “Old Vatican Rooms” (Vatican Museum, Rome, Italy) and belong to three different frescoes known as: “Il Passaggio del Mar Rosso” (pmr), located in the Sistine Chapel, “Il Parnaso” (p), and lastly the specimen from the “Room of Heliodorus” (hr), located in the Old Vatican Rooms; examples are shown in Figure 2.
Instrumental techniques applied
10–20 mg of each sample (i.e., few granules of material coming from the intonaco/intonachino or intonaco/arriccio, in the case of Roman and Renaissance frescoes, respectively) obtained during the restoration of the frescoes were gently ground up and placed in an alumina crucible. They were then subjected to controlled thermal scanning from room temperature up to 1000°C at a heating rate of 10°C min−1 in an air flow of 100 cm3 min−1, using a Mettler TG 50 thermobalance connected to a Mettler TC 10 A processor and a Dupont TA 1200 DTA instrument coupled to a TA 2000 processor [5,23].
In conclusion, PCA analysis has unequivocally shown how the ancient Roman mortar samples are much richer in binder (calcium carbonate) and contain less filler (see TG residue values at 1000°C), than the Renaissance mortar samples: indeed, the difference between the higher values of the TG residue of the first five samples in Table 1, which correspond to Renaissance frescoes, and the lower values of the remaining last five, which are the Roman ones, can be ascribed to a higher amount of filler in the former. This is likely due to the presence of the intonachino containing a high percentage of binder in the samples of ancient Roman mortar (Campanella et al., 1998b) , which is absent in the samples of Renaissance mortar (Campanella et al., 1998a) . The percentage of organic substance in the latter may be attributed to the relatively small but nevertheless more significant traces of more or less burnt straw contained in the Renaissance arriccio samples.
Lastly, also in this case it was demonstrated how, also in the present research, the coupling of thermal analysis and chemometrics represents a useful, simple and advantageous approach for dealing with problems of characterization and classification of different kinds of archaeological finds and cultural heritage.
We are grateful to Dr. Giovanna Bandini of the Roman National Museum and to Dr. Nazzareno Gabrielli of the Scientific Cabinet of the Vatican Museum for providing the samples studied in the present research.
- Gary M. Die Bedeutung der Mörtel in der Denkmalpflege. Die Denkmalpflege. 1921;23:102–4.Google Scholar
- Bakos F, Cimitan L, Rossi PP, Zaninetti A. Caratterizzazione petrologica e chimica di malte e pozzolane antiche. Materiali e Strutture. 1994;4:1–20.Google Scholar
- Duran A, Robador MD, Jimenez de Haro MC, Ramirez-Valle V. Study by thermal analysis of mortars belonging to wall paintings corresponding to some historical buildings of Sevillian art. J Thermal Anal Calorim. 2008;92:353–9.View ArticleGoogle Scholar
- Corti C, Rampazzi L, Bugini R, Sansonetti A, Biraghi M, Castelletti L, et al. Thermal analysis and archaeological chronology: the ancient mortars of the site of Baradello (Como, Italy). Thermoch Acta. 2013;572:71–84.View ArticleGoogle Scholar
- Vecchio S, La Ginestra A, Frezza A, Ferragina C. The use of thermoanalytical tchniques in the characterisation of ancient mortars. Thermoch Acta. 1993;227:215–23.View ArticleGoogle Scholar
- Pavía S, Caro S. An investigation of Roman mortar technology through the petrographic analysis of archaeological material. Construct Build Mater. 2008;22:1807–11.View ArticleGoogle Scholar
- Degryse P, Elsen J, Waelkens M. Study of ancient mortars from Sagalassos (Turkey) in view of their conservation. Cem Concr Res. 2002;32:1457–63.View ArticleGoogle Scholar
- Pecchioni E, Fratini F, Cantisani E. The ancient mortars, an attestation of the material culture: the case of Florence. Periodico di Mineralogia. 2006;75:255–62.Google Scholar
- Elsen J. Microscopy of historic mortars – a review. Cem Concr Res. 2006;36:1416–24.View ArticleGoogle Scholar
- Brown GE. Analyses and history of cement: a 12,000 year old historical review together with test data on ancient concretes, plasters, stuccos and mortars from 90 sites throughout the world. Keswick, UK: Gordon E. Brown Consultants; 1996.Google Scholar
- Foster W. Grecian and Roman stucco, mortars and glass. J Chem Educ. 1934;11:223–5.View ArticleGoogle Scholar
- Gatta T, Tomassetti M, Ciancio Rossetto P, Grossi R, Visco G, Campanella L. Applications of instrumental analysis and chemometry to old roman mortars stuccos. Curr Anal Chem. 2010;6:80–7.View ArticleGoogle Scholar
- Campanella L, Marinucci F, Tomassetti M. Rimozione delle alterazioni chimiche prodotte dall’inquinamento ambientale su malta affrescata del XVI secolo. In: Atti del IV Congresso Nazionale di Chimica Ambientale, 17–20 Giugno 1998, Mantova. 1998. p. 207Google Scholar
- Campanella L, Positano M, Tomassetti M. Analisi e caratterizzazione di affreschi del II secolo D.C. con tecniche di analisi chimica strumentale. In: Atti del XIV Congresso Nazionale di Chimica Analitica, 12–13 Giugno 1998, Numana (Ancona). 1998. p. 69Google Scholar
- Gatta T, Campanella L, Coluzza C, Mambro V, Postorino P, Tomassetti M, et al. Characterization of black pigment used in 30 BC fresco wall paint using instrumental methods and chemometry. Chem Cent J. 2010;6:S2–9.View ArticleGoogle Scholar
- Campanella L, Gregori E, Tomassetti M, Visco G. Identification of different types of imperial age marbles finds using instrumental chemical analysis and pattern recognition analysis. Ann Chim. 2001;91:701–18.Google Scholar
- Campanella L, Flamini P, Grassi R, Tomassetti M. Study and characterization by means of instrumental analytical methods of statues and fictile finds from different historical or prehistoric periods. In: Pancella R, editor. Conservation et restauration des biens culturels: actes du congrès LCP 1995, Montreux 24–29 septembre 1995. Preservation and restoration of cultural heritage: Proceeding of the 1995 LCP Congress, Montreux 24–29 September 1995. Lausanne, Switzerland: Ecole polytechnique fédérale de Lausanne; 1995. p. 671–7.Google Scholar
- Tomassetti M, Marini F, Campanella L, Coppa A. Archaeometric classification of ancient human fossil bones, with particular attention to their carbonate content, using chemometrics, thermogravimetry and ICP emission. Chem Cent J. 2014;8:26.View ArticleGoogle Scholar
- Istituto Geografico De Agostini. Storia dell’Arte, vol. 5. Novara, Italy: De Agostini Editore; 1976. p. 256.Google Scholar
- Redig de Campos D. Raffaello nelle Stanze. Milano, Italy: Aldo Martello Editore; 1965.Google Scholar
- Jolliffe IT. Principal component analysis. Heidelberg, Germany: Springer Verlag; 2002.Google Scholar
- Jackson JE. A user’s guide to principal components. New York, NY: Wiley; 2003.Google Scholar
- Wendlandt WW. Thermal Analysis. 3rd ed. New York, NY: Wiley Interscience; 1986.Google Scholar
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