Phase-composition analysis of the glazed tile bodies from the Bao'ensi site

The XRD traces of the glazed tile bodies are shown in Fig. 2. The phase composition of each body sample was obtained, as shown in Table 1.

Fig. 2. XRD traces of representative body samples.

Table 1. The phase compositions and firing temperatures of representative Bao'ensi site body samples.

The glazed tile bodies of the Bao'ensi site consist mainly of quartz and mullite, along with trace amounts of albite, rutile, muscovite, hematite and pyroxene (Table 1). Therefore, the body materials have a comparable composition, along with certain differences, suggesting partial consistency in the selection of body materials.

A series of physical and chemical changes took place during the firing process of the glazed tiles. The mineralogical composition of the tiles reflects the heating changes of the original materials, mainly clays. Clays with various mineralogical compositions yield various end products when heated, which may be used to identify the mineralogical composition of the original clay (Li, Reference Li2001). The glazed tiles were fired under low temperatures. Kaolinite (Al₂O₃⋅2SiO₂⋅2H₂O) is the main source of mullite (3Al₂O₃⋅2SiO₂) detected in all of the samples (Dubois et al., Reference Dubois, Murat, Amroune, Carbonneau and Gardon1995). Therefore, the quartz phase in the body materials belongs to α-quartz. The main component of quartz is SiO₂, which often contains a number of impurities such as Al₂O₃, Fe₂O₃, CaO, MgO, TiO₂, etc. These impurities represent other minerals (e.g. carbonate (dolomite, calcite and magnesite), feldspar, rutile, mica and iron oxide) being included in the process of mineral formation. The structural water in kaolinite is released during hydroxylation and the crystal structure is destroyed to form metakaolinite in the temperature range of 450–650°C (Equation 1). Metakaolinite begins to transform into Al–Si spinel-type structures at 925°C (Equation 2), and the Al–Si spinel begins to transform into mullite and cristobalite at 1050–1100°C (Equation 3). Due to the presence of flux oxides (such as K₂O and CaO), the formation temperature of mullite in the body is reduced, and cristobalite does not form in the body phase, implying that the firing temperature of the body was ~1000°C. Through thermal expansion analysis (Tite, Reference Tite1969), it can be inferred that the firing temperature of the glazed tile body was 1000–1100°C (Table 1).

(1)$$\mathop {{\rm A}{\rm l}_2{\rm O}_3\cdot 2{\rm Si}{\rm O}_2\cdot 2{\rm H}_2{\rm O}}\limits_{( {{\rm kaolinite}} ) } \to \mathop {{\rm A}{\rm l}_2{\rm O}_3\cdot 2{\rm Si}{\rm O}_2 + 2{\rm H}_2{\rm O}}\limits_{\hskip -3pc{( {{ \rm metakaolinite}} ) }} $$

(2)$$2( {\rm A}{\rm l}_2{\rm O}_3\cdot 2{\rm Si}{\rm O}_2) \to 2{\rm A}{\rm l}_2{\rm O}_3\cdot 3{\rm Si}{\rm O}_2 + {\rm Si}{\rm O}_2$$

(3)$$3( 2{\rm A}{\rm l}_2{\rm O}_3\cdot 3{\rm Si}{\rm O}_2) \to \mathop {2( 3{\rm A}{\rm l}_2{\rm O}_3\cdot 2{\rm Si}{\rm O}_2) }\limits_{( {\rm mullite}) } + \mathop {\;5{\rm Si}{\rm O}_2}\limits_{( {{\rm cristobalite}} ) } $$

The melting point of albite (NaAlSi₃O₈) is ~1100°C, and the melting of quartz and mullite at high temperatures is rapid in the presence of albite flux. Muscovite usually coexists with feldspar and quartz. Pyroxene is a common silicate mineral. Hematite is the main mineral form of Fe₂O₃, and it has a melting point of ~1250–1270°C. Rutile, a TiO₂ polymorph generally containing >95% TiO₂, has a melting point of ~1500–1600°C.

The phase composition combined with the firing temperature indicate that the raw material was concentrated and that the firing processes of the glazed tile body samples had similarities.

Analysis of the chemical composition of the glazed tile bodies

The chemical compositions of the 56 glazed tile sample bodies were determined using EDXRF. Some of the EDXRF data are shown in Table 2.

Table 2. Chemical composition of the Bao'ensi glazed tile body samples (wt.%).

Archaeological reports show that the Nanjing Jubaoshan kiln site was the main location for providing royal and official buildings in Nanjing with glazed pottery products (Nanjing Museum, 1962; Chen, Reference Chen2009). In addition, ancient works such as the ‘Collected Statutes of the Ming Dynasty’ (明会典), ‘Exploitation of the Works of Nature’ (天工开物) and ‘Taiping Prefecture Chorography’ (太平府志) report that the material that makes up the body of the Jubaoshan glazed tiles consists of a white clay from the Dangtu area, Anhui (Chen, Reference Chen2009). Based on this information, the data from the Dangtu glazed tile body samples from previous research (Ding et al., Reference Ding, Duan, Kang, Wu and Miao2011; Yang, Reference Yang2018), numbered as AM(DY), were used to explore whether the raw material of the glazed tile bodies from the Bao'ensi site originates from Dangtu.

Analysis of the EDXRF data

The chemical composition of the glazed tile bodies analysed (Fig. 3) was used to determine the possible differences between the glazed tile bodies from the Bao'ensi area and the Dangtu area.

Fig. 3. Dispersion analysis of the glazed tile body samples. AM(DY) = Dangtu glazed tile body samples.

The Al₂O₃ content of the Bao'ensi site body samples varies between 22.10% and 25.60%, while the Al₂O₃ content of the Dangtu glazed tile body samples varies between 20.11% and 24.78% (Fig. 3a & Table 2). The two sets of samples have generally comparable Al₂O₃ contents, with only a few samples having different Al₂O₃ contents. The SiO₂ content of the Bao'ensi site body samples varies between 65.30% and 72.10%, while the SiO₂ content of the Dangtu glazed tile body samples varies between 64.60% and 70.67%. Hence, the two sample sets have comparable SiO₂ contents. In addition, the K₂O contents of the Bao'ensi site body samples and the Dangtu glazed tile body samples are comparable (3.40–5.40% and 3.47–4.58%, respectively). In contrast, the Bao'ensi site body samples have a greater CaO content than their Dangtu glazed tile body sample counterparts (0.30–3.60% and 0.19–0.44%, respectively; Fig. 3b). In addition, the TiO₂ contents of the two sets of samples are generally variable (Fig. 3c). Finally, the Fe₂O₃ contents of the Bao'ensi site bodies and the Dangtu glazed tile body samples are generally comparable (1.60–3.50% and 1.63–2.74%, respectively), with some samples from the Bao'ensi site having a greater Fe₂O₃ content. Therefore, the two sites have comparable chemical compositions overall.

Factor analysis of the EDXRF data

Factor analysis converts multiple variables into a few uncorrelated comprehensive indicators, establishes the possible correlations between multiple variables and extracts two to three factors that most reflect the data. Based on such an analysis, the results (data points) reflect the relationships between samples (i.e. adjacent sample points have similar properties and belong to the same group) and the relationships between elements and samples (variables). Thus, data points within the same area will be characterized by adjacent variables (Xue, Reference Xue2013).

Figure 4 depicts the factor-loading diagram of the glazed tile body samples from the Bao'ensi site and the Dangtu glazed tile body samples. Factor analysis was performed using the SPSS software package. Five chemical components, namely Al₂O₃, SiO₂, K₂O, CaO and Fe₂O₃, were selected for factor analysis, and two factors (i.e. F ₁ and F ₂) were extracted, explaining 73% of the total variance (Equations 4 and 5):

(4)$$F_1 = 0.327{\rm A}{\rm l}_2{\rm O}_3\;\ndash\;0.4{\rm Si}{\rm O}_2 + 0.3{\rm K}_2{\rm O\ } + 0.155{\rm CaO\ } + 0.21{\rm F}{\rm e}_2{\rm O}_3$$

(5)$$F_2 = \ndash 0.208{\rm A}{\rm l}_2{\rm O}_3 + 0.062{\rm Si}{\rm O}_2\;\ndash\;0.353{\rm K}_2{\rm O\ } + 0.587{\rm CaO\ } + 0.511{\rm F}{\rm e}_2{\rm O}_3$$

Fig. 4. Factor analysis of the glazed tile body samples. AM(DY) = Dangtu glazed tile body samples.

Figure 4 shows that the data points for the Bao'ensi site glazed body samples display considerable scattering, and those for the Dangtu glazed tile body samples plot in the same area, overlapping with a significant proportion of the Bao'ensi site glazed body samples thus indicating similarities in the chemical composition of the two groups of glazed tile samples. Therefore, the raw materials for some of the Bao'ensi site glazed body samples may originate from Dangtu. However, some of the Bao'ensi site glazed body samples do not match the composition of the Dangtu samples (Fig. 4), indicating that there was another source of the raw materials for these samples.