Revealing the Individual Effects of Firing Temperature and Chemical Composition on Raman Parameters of Celadon Glaze

Abstract

The Raman polymerization index (or I_P value) is often used as a positive indicator of the firing temperature of the glazes of ancient ceramics. Previous studies have also reported that the I_P value was negatively correlated with the chemical composition of the glaze. However, these findings were derived from data on the potential integrative effects of temperature and composition. To explore their individual effects, we prepared celadon glaze samples with controlled composition and firing temperatures. Particularly, according to the typical content of K₂O and CaO in celadon glaze, four categories, or, in total, fifteen compositional formulations, were designed, and each formulation was fired at multiple temperatures (from 1180 to 1250 °C by 10 °C). The chemical compositions and the glassy matrix of samples were analyzed by an energy-dispersive X-ray fluorescence spectrometer and Raman spectroscopy, respectively. A positive correlation between firing temperature and I_P value (correlation coefficient = 0.56) was detected only in the samples with low contents of K₂O and CaO. However, no significant correlation was found when combining the samples with broad variation in chemical composition. Additionally, both the K₂O content and CaO content were negatively related to the I_P value, with regression coefficients of −9.645 and −5.332, respectively. Our results help to clarify the technology of ancient ceramic production and to improve its preservation.

1. Introduction

Raman spectroscopy, being an optical method, offers a great opportunity to non-destructively detect the nanomaterials and nanostructures within cultural heritage objects, especially those made of glass [1,2,3,4]. For example, Raman spectroscopy can detect molecular and lattice vibrations of glassy silicates within the glazes, enamels, and pigments of ancient ceramic samples, and can provide valuable information about their provenance, production process, and even their preservation conditions [1,5,6,7,8]. Therefore, Raman spectroscopy has drawn increasing interest in the study of ancient ceramics [5,6,7,8,9,10].

Using the Raman data of ceramic samples, research has revealed Raman features and their association with the characteristics of chemical composition as well as the parameters of production technology (i.e., firing temperature). The classical spectral decomposition of the Si-O bending (~500 cm⁻¹) and stretching (i.e., ~1000 cm⁻¹) envelopes was firstly proposed to approximate the distribution of the [SiO₄]⁴⁻ tetrahedral structure units, which contained different amounts of bridging oxygen. This provided an indication of the nature and quantity of fluxing oxides used in the manufacturing process [11,12].

In 2003, Philippe introduced the polymerization index (denoted as I_P value), which was defined as the peak area ratio of the Si-O bending and stretching envelopes, to quantify the connectivity of the glassy structures within the glaze or enamels of ceramic samples [10]. Since then, some research has employed I_P values to study ancient Western or Chinese ceramic samples, and a positive relationship between the I_P value and the firing temperature has been reported [3,4,5,6]. Meanwhile, researchers also found a negative relationship between the contents of fluxing oxides (such as Na, K, Ca, and/or Pb oxides) and I_P value. These contents could influence the connectivity of the tetrahedral units, de-polymerize the glass network, and consequently lead to changes in the Raman spectrum and I_P value [3,13].

However, when it was used in previous studies, the I_P value was calculated based on samples from different categories of glassy silicates featured by different melting/processing temperatures and varied chemical compositions [3,14]. Hence, when these previous studies drew conclusions regarding the individual effects of firing temperature or chemical composition on the I_P value, they might have been using data on the integrative effects of temperature and composition, indicating the possibility of inaccuracy in their findings. Additionally, with certain types of ceramics for which the firing temperature varies relatively little, it is still inconclusive whether there is a positive correlation between the I_P value and the firing temperature. For example, a recent study of real celadon samples (which are an important category of ancient Chinese ceramics) with significant variations in their composition provided inconsistent evidence that the I_P value did not show a positive relation with the firing temperature [6,11].

According to these conflicting facts, we systematically analyzed the individual effects of firing temperature and chemical composition on the I_P value and other Raman parameters based on celadon glaze samples. Our results may enhance the application of Raman spectroscopy in the analysis of ancient ceramics. To conduct the study, we prepared glazes by designing a series of compositional formulations and firing at different temperatures. The chemical compositions and the glassy matrix of glazes were analyzed by an energy-dispersive X-ray fluorescence spectrometer (ED-XRF) and Raman spectroscopy, respectively.

2. Materials and Methods

2.1. Preparation of Samples

Celadon has been developed for hundreds of years in China, undergoing considerable changes in chemical composition and firing temperature and having a major impact on the manufacturing of other types of ancient Chinese ceramics. Recently, some inconsistent evidence has emerged regarding the relationship between firing temperature and Raman polymerization index (I_P value) for ancient celadon samples. To resolve this contradiction and to fully explore the effects of firing temperature and chemical composition on the Raman parameters, we prepared celadon glaze samples with different firing temperatures and different chemical compositions.

A series of formulations were determined in order to reproduce the celadon glaze reported in the literature. It was shown in previous studies [5,15] that the major materials forming the glassy network within the celadon glaze were SiO₂ and Al₂O₃, with contents of 60–72% and 10–16%, respectively. In addition, two categories of flux composition were used for the real samples: one with high K₂O content and low CaO content (denoted as HKLC), and the other with low K₂O content and high CaO content (denoted as LKHC). The thresholds between the high and low K₂O and CaO contents were estimated to be 3.4% and 9.5%, respectively [15]. Therefore, we defined the HKLC and LKHC formulations to mimic the chemical composition of real celadon samples. Furthermore, we added formulations of both high/low contents of K₂O and CaO (denoted as HKHC and LKLC, respectively) to cover the known compositional range of celadon glaze. In summary, four categories and a total of fifteen formulations were determined as follows (Table S1).

2.2. Celadon Glaze Synthesis

Rock powders of feldspars, calcite, talc, kaolin, and quartz were employed as base glaze compositions, with the addition of iron oxide in the form of chemical materials to obtain glazes with a certain performance. For each formulation, several replications (5 g each) were placed into mullite crucibles and fired using an electric furnace at 1180 $℃$, 1190 $℃$, 1200 $℃$, 1220 $℃$, 1230 $℃$, 1240 $℃$, and 1250 $℃$, respectively. The firing procedure was as follows: (1) increasing from room temperature to target temperature in 3 h by a heating rate of about 6.67 °C/min; (2) parking for 1 h at the target temperature; and then (3) natural cooling to room temperature.

2.3. Analytical Methods

2.3.1. XRF Analyses

For each sample, the chemical composition of the glaze surface was analyzed by using X-ray fluorescence (XRF) spectroscopy (EAGLE II XXL, EDAX Company, Mahwah, NJ, USA). The unit was equipped with a rhodium X-ray tube and a Si (Li) detector with an energy resolution of 145 eV at 5.9 keV for Mn–Ka. The equipment was calibrated using a copper sheet. For XRF measurements, the incident X-ray tube voltage was 25 kV, the current was 600 µA, and the micro-beam size was 0.3 mm.

2.3.2. Raman Spectroscopy Analyses

Raman spectra were obtained with the 532nmNd: YAG laser using a Jobin–Yvon HR 800 LabRam Spectrometer (focal length 800 mm, Olympus microscope, 50 × long working distance objective lens, spectral range 150–1500 cm⁻¹ with ~2 cm⁻¹ resolution). Each spectrum was collected for 600 s.

Firstly, the collected spectra were processed using Labspec software to remove the background. We placed linear segments at the same locations and used minimal reference points (between 6 and 8) and spectral windows as recommended in the literature [3,4].

Secondly, the curve fitting was carried out using Gaussian functions to deconvolute the Si–O stretching, and bending ranges were used for the identification of the spectral components. As recommended in [13], we added three components for stretching ranges from 850~1250 cm⁻¹ and initiated the peak positions of 950 cm⁻¹, 1050 cm⁻¹, and 1150 cm⁻¹ for the Q¹, Q², and Q^3–4, respectively. The compound component of Q^3–4 could be attributed to the indistinguishable wavenumber shift, which was induced by the small connection of the last nonbridging oxygen and was affected by neighboring ions [13].

To perform curve fitting for a batch of Raman spectra, we used the open-sourced Python package lmfit [16] to extract the components. All the codes for this study are available online: https://github.com/yunPKU/Raman_curve_fitting (accessed on 1 May 2023).

Thirdly, the integral areas under the Si-O bending (~500 cm⁻¹) and stretching (i.e., ~1000 cm⁻¹) envelopes were calculated and denoted as A₅₀₀ and A₁₀₀₀, respectively. The polymerization index I_P was consequently calculated as the ratio of the bending and the stretching envelopes (i.e., A₅₀₀/A₁₀₀₀). Additionally, the area ratios of the spectral components (i.e., Q¹, Q², and Q^3–4) versus the total area of the stretching envelope were calculated and abbreviated as A¹, A², and A³⁴, respectively.

Due to the incomplete melting of some crystals, such as quartz, microcline, and wollastonite, some spectra of the samples showed obvious peaks of quartz (e.g., at 127, 204, and 464 cm⁻¹), of microcline (e.g., at 154, 264, 286, 402, and 511 cm⁻¹), or of wollastonite (e.g., at 637 and 968 cm⁻¹), which would incur significant bias in the calculation of the I_P value and the extraction of the spectral components. We therefore excluded these samples from the following analysis. The Raman parameters of the selected spectra are summarized in

Table 1. Main Raman parameters of imitated glaze samples. Ip, index of polymerization; vQⁿ: center of gravity wavenumber (cm⁻¹) of the Si-O stretching Qⁿ component; Aⁿ, component area (% of the peak area) and ratio.

Category	ID	Firing Temperature $\left(\mathbf{℃}\right)$	IP	vQ1	vQ2	vQ34	A1	A2	A34
HKHC	1	1200	1.402	936.217	1030.949	1152.197	0.247	0.639	0.115
		1220	1.304	933.388	1027.712	1147.434	0.248	0.637	0.114
		1230	1.399	935.455	1027.446	1144.971	0.253	0.602	0.144
		1240	1.411	934.987	1027.231	1145.439	0.242	0.613	0.145
		1250	1.407	935.049	1027.212	1144.966	0.245	0.608	0.147
HKHC	2	1200	1.085	933.600	1031.585	1150.664	0.270	0.655	0.075
		1220	1.097	934.328	1032.670	1151.762	0.278	0.649	0.073
		1230	1.235	935.792	1035.594	1150.158	0.304	0.646	0.050
		1240	1.117	934.087	1031.876	1149.828	0.268	0.652	0.080
		1250	1.103	936.013	1034.744	1154.347	0.276	0.652	0.072
HKHC	3	1180	1.090	965.550	1054.033	1100.000	0.615	0.067	0.317
		1200	1.059	933.320	1033.548	1161.137	0.266	0.683	0.051
		1230	1.055	933.228	1033.988	1162.803	0.265	0.686	0.050
		1240	0.961	942.372	1042.457	1169.354	0.359	0.607	0.035
		1250	0.979	948.688	1050.454	1165.043	0.447	0.504	0.049
HKHC	4	1220	0.975	931.523	1031.017	1160.727	0.291	0.668	0.042
		1250	1.057	933.168	1033.639	1161.156	0.265	0.684	0.051
HKLC	5	1180	1.389	937.658	1018.156	1134.464	0.215	0.577	0.208
		1190	1.336	956.219	1053.971	1158.782	0.449	0.442	0.109
		1200	1.443	955.640	1050.736	1161.613	0.386	0.507	0.107
		1220	1.406	954.699	1050.273	1161.608	0.384	0.517	0.099
		1230	1.430	958.013	1054.013	1160.424	0.419	0.463	0.118
		1240	1.349	953.702	1050.330	1159.817	0.412	0.486	0.101
		1250	1.387	950.338	1045.127	1158.780	0.353	0.543	0.103
HKLC	6	1180	1.358	971.648	1055.924	1115.197	0.610	0.060	0.330
		1200	1.250	972.945	1066.664	1140.468	0.621	0.193	0.186
		1220	1.261	973.368	1067.826	1143.720	0.610	0.211	0.179
		1230	1.299	973.974	1066.246	1140.489	0.605	0.193	0.202
		1240	1.300	973.591	1065.126	1137.686	0.613	0.181	0.206
		1250	1.322	973.524	1064.954	1139.166	0.604	0.189	0.207
HKLC	7	1180	1.263	945.635	1032.532	1145.551	0.307	0.556	0.136
		1190	1.323	958.971	1057.647	1162.940	0.447	0.474	0.079
		1200	1.348	962.515	1062.222	1156.770	0.492	0.386	0.121
		1220	1.327	956.923	1057.188	1160.808	0.439	0.479	0.082
		1230	1.315	959.453	1059.989	1160.264	0.476	0.429	0.095
		1240	1.340	959.133	1060.000	1161.140	0.456	0.453	0.091
		1250	1.324	957.065	1057.199	1160.499	0.436	0.478	0.086
HKLC	8	1180	1.490	942.667	1026.198	1145.547	0.242	0.577	0.180
		1200	1.442	943.656	1035.907	1154.974	0.290	0.588	0.122
		1220	1.522	948.386	1039.389	1157.164	0.304	0.558	0.138
		1230	1.477	945.633	1037.995	1156.246	0.297	0.572	0.131
		1240	1.376	941.162	1035.075	1154.635	0.279	0.606	0.115
		1250	1.436	944.415	1037.463	1156.141	0.292	0.584	0.124
LKHC	9	1180	1.210	932.378	1032.144	1163.554	0.244	0.686	0.070
		1200	1.168	931.503	1032.614	1164.847	0.247	0.690	0.063
		1220	1.186	930.575	1030.810	1163.317	0.237	0.698	0.064
		1230	1.161	930.667	1030.600	1163.007	0.242	0.694	0.064
		1240	1.231	931.616	1031.680	1162.464	0.241	0.686	0.073
LKHC	10	1180	1.179	931.839	1032.639	1163.033	0.249	0.691	0.060
		1190	1.206	932.093	1032.047	1160.807	0.236	0.693	0.071
		1200	1.161	931.523	1032.558	1163.113	0.246	0.692	0.062
		1220	1.135	931.152	1032.566	1162.765	0.252	0.691	0.058
		1230	1.126	931.128	1032.002	1163.163	0.245	0.697	0.058
		1240	1.147	932.112	1033.029	1163.231	0.250	0.690	0.059
		1250	1.128	931.296	1031.457	1161.749	0.240	0.697	0.063
LKHC	11	1180	1.117	932.706	1032.721	1159.422	0.254	0.684	0.062
		1190	1.064	931.533	1032.982	1163.018	0.254	0.695	0.050
		1200	1.070	931.339	1032.207	1161.628	0.249	0.696	0.055
		1220	1.098	931.915	1032.381	1160.946	0.242	0.699	0.059
		1230	1.080	931.774	1032.475	1161.933	0.247	0.696	0.057
		1240	1.130	932.735	1033.563	1161.098	0.247	0.692	0.060
		1250	1.142	932.673	1033.310	1160.366	0.255	0.689	0.056
LKLC	12	1230	1.619	933.696	1021.900	1145.400	0.229	0.588	0.182
		1240	1.676	935.377	1023.197	1147.935	0.242	0.580	0.177
		1250	1.621	934.660	1022.068	1145.617	0.230	0.585	0.185
LKLC	13	1220	1.621	938.267	1029.544	1154.787	0.238	0.609	0.153
		1230	1.599	937.893	1028.460	1153.184	0.244	0.600	0.156
		1240	1.724	940.302	1029.173	1154.470	0.243	0.588	0.170
		1250	1.621	938.663	1029.577	1154.963	0.253	0.596	0.151
LKLC	14	1220	1.455	939.458	1030.678	1153.538	0.248	0.603	0.149
		1230	1.597	941.589	1032.081	1155.906	0.242	0.602	0.156
		1240	1.640	940.850	1031.477	1155.282	0.263	0.587	0.150
		1250	1.570	938.577	1029.794	1153.413	0.250	0.604	0.147
LKLC	15	1200	1.454	929.745	1015.884	1135.535	0.240	0.579	0.181
		1220	1.606	930.965	1011.761	1128.258	0.220	0.532	0.247
		1230	1.711	932.035	1010.162	1130.153	0.219	0.520	0.261
		1240	1.722	930.239	1008.890	1125.721	0.204	0.525	0.271

.

2.3.3. Statistical Analysis

We used some multivariate statistical models to explore the individual effects of firing temperature and chemical composition on the Raman spectrum. Firstly, we used the partial correlation coefficient to quantify the individual effect of a specific flux oxide by adjusting the firing temperature and/or the contents of other flux oxides. Secondly, we used the Pearson correlation coefficient to investigate the association of I_P value with the firing temperature within a particular category of formulations. A p-value < 0.05 was considered statistically significant. All of the calculations were performed using the open-source software JASP [17].

3. Results

3.1. Influence of Firing Temperature on Raman Spectrum

For the spectra of typical samples (Figure 1), they each had two peaks within the range of 300–1350 cm⁻¹: one was centered near 500 cm⁻¹ and the other near 1000 cm⁻¹, corresponding to the bending and asymmetric stretching vibration of the [SiO₄]⁴⁻ tetrahedral Si-O bond in the glass [3].

We found that the amplitude of the stretching envelope was more affected by the firing temperature than that of the bending envelope. Particularly, for the LKLC sample, the amplitude of the stretching peak decreased strictly with the increase in firing temperature (Figure 1A). For the HKHC sample, however, the amplitude of its spectra was the least affected by the firing temperature among the samples from the four categories.

We calculated the Pearson correlation between the I_P value and the firing temperature for these spectra to quantify how the amplitude of the stretching peak changed with the firing temperature. Firstly, by combining the samples of all four of the categories, we found a positive, but non-significant, correlation between I_P and the firing temperature with a correlation coefficient of 0.173 (p-value = 0.133), suggesting that no evidence for the correlation between I_P value and firing temperature exists without controlling the chemical composition.

Secondly, we explored the correlation between firing temperature and I_P value for samples within each category (Figure 2). For the LKLC samples, we observed a positive correlation between the firing temperature and the I_P value, with a correlation coefficient of 0.56 (p value = 0.03), suggesting that the firing temperature played a considerable role in shaping the stretching peaks of these samples. However, for the other three categories, namely, HKLC, LKHC, and HKHC, no significant correlations were found, that is, the correlation coefficients were −0.07 (p-value = 0.78), −0.02 (p-value = 0.92), and 0.02 (p-value = 0.95), respectively (Figure 2).

3.2. Influence of Chemical Composition on Raman Spectrum

When fixed at a typical firing temperature, i.e., 1250 $℃$, the stretching peaks of these spectra were more affected by the chemical composition than those of the bending peaks were (Figure 3A). Particularly, for the samples with higher CaO concentrations (Figure 1A, black and green curves), the amplitudes of their stretching peaks were higher those of the samples with lower contents of CaO (Figure 3A, blue and red curves). Similarly, due to the difference in the K₂O contents, the black curves and the blue curves (i.e., spectra with high K₂O content) had higher stretching peaks than the green and red curves did (i.e., spectra with low K₂O content), respectively. These findings suggest that both K₂O and CaO have a negative effect on the amplitude of the stretching peak.

We used partial correlation coefficients to quantify how the amplitude of the stretching peak changed with a particular fluxing oxide content (Figure 4). We estimated the partial correlation (conditioned on the temperature and CaO content) between K₂O content and I_P value to be −0.82 (p-value < 0.001). We also estimated the partial correlation (conditioned on the temperature and K₂O content) between CaO content and I_P value as −0.945 (p-value < 0.001). These results were consistent with the observations of the heights of the spectra and their relationships in Figure 3.

Furthermore, we built a multivariate regression model of the effect of CaO and K₂O content (in mol%) on the I_P value. Note that we ignored the firing temperature, as it did not show any correlation with the I_P value conditioned on the chemical composition (Figure 4C). We found that the model fitted to the data very well, as 89.7% of the variation in I_P value could be explained (Figure 5). Furthermore, we found that increasing each mole in the K₂O content and CaO content was associated with −9.645 and −5.332 units of change in the I_P value, respectively (

Table 2. Regression coefficients of the model, obtained for the prediction of the polymerization index (I_P) using the K₂O and CaO content (in mol%).

Variable *	Linear Regression Coefficients #			t	Significance
	$\mathit{\beta }$	Standard Error	Standardized Coefficients
(Constant)	2.495	0.053		47.473	<0.001
K2O	−9.645	0.778	−0.497	−12.400	<0.001
CaO	−5.332	0.213	−1.005	−25.068	<0.001

* Predictors: Constant: K₂O, and CaO; dependent variable: polymerization index (I_P). ^# The fitted model is I_P = 2.495 − 9.645 × K₂O − 5.332 × CaO.

), suggesting that K₂O has a greater influence on the I_P value and the degree of polymerization of the glaze than CaO does.

In addition, we explored the effect of chemical composition on the I_P value for different classes of samples (Figure 6). We firstly divided the samples into two groups according to their CaO content, i.e., one class had high CaO content (i.e., both LKHC category and LKHC category), while the other had low CaO content (i.e., both LKLC category and HKLC category). We found that the regression slopes of I_P on the K₂O content (in mol%) for the samples of these two groups were −1.83 (p-value = −0.505) and −11.24 (p value < 0.001), respectively (Figure 6A), suggesting that K₂O only exerted its effect on I_P value for the samples with low CaO contents. Similarly, we estimated the effects of CaO content on I_P value for the low-K₂O samples (i.e., both HKLC category and LKLC category) and high-K₂O samples (i.e., both HKHC category and HKLC category), and found values of −6.08 (p value < 0.0001) and −3.82 (p value < 0.0001), respectively (Figure 6B), suggesting that CaO content continued to have a considerable effect on the I_P value regardless of the K₂O content.

We also observed considerable differences in the shapes of the stretching peaks across the four sample categories (Figure 3A). For the spectra of the samples with higher K₂O contents (i.e., the HKHC and HKLC samples), the stretching envelopes peaked around 950~980 cm⁻¹ (Figure 3A, black and blue curves). For the LKHC samples, their stretching envelopes peaked around 1050 cm⁻¹ (Figure 3A, green curves). For the bending peaks, there were no considerable differences in shape between the samples, indicating that the bending peak was less affected by the chemical composition.

To accurately explore the quantitative relationship between chemical content and spectral shape, we correlated the content of K₂O and CaO with the area ratios of the spatial components (i.e., Qⁿ units) of the stretching peaks (Figure 7). By adjusting the firing temperature and CaO content, we found that the area ratios of A1 showed strong positive correlations with the content of K₂O, with partial correlation coefficients of 0.725 (p-value < 0.001) (Figure 7A). The observed correlation was consistent with the increasing trend of Q¹ components with potassium content in medieval-like glass samples [14]. Furthermore, when adjusting the firing temperature and the K₂O content, we found that the area ratio of A³⁴ was negatively related to the CaO content, with a coefficient of −0.553 (p-value < 0.001) (Figure 7F). This was consistent with the findings of other studies on celadon samples [7,13].

The component of Q², which was jointly affected by the intensity of both Q¹ and Q³⁴, with correlation coefficients of −0.912 (p-value < 0.001) and −0.683 (p-value < 0.001), respectively, showed contrary correlations with both K₂O (${\rho }_{K_{2}O,A^2|CaO,T}$= −0.536, p-value < 0.001) and CaO (${\rho }_{CaO,A^2|K_{2}O,T}$ = 0.242, p-value = 0.032).

4. Discussion

In this systematic analysis of celadon glaze samples using Raman spectroscopy, we revealed that the firing temperature and chemical composition had individual effects on the Raman polymerization index (I_P value) and other parameters of celadon glaze. On the one hand, the firing temperature was positively related with the I_P value (correlation coefficient = 0.56, p value < 0.001), but only in samples with low contents of K₂O and CaO (LKLC). However, no significant correlation was found when combining the samples which had wide variation in their chemical compositions. On the other hand, with regard to the chemical composition, both the K₂O content and the CaO content were negatively related to the I_P value, with regression coefficients of −9.645 and −5.332, respectively. In addition, K₂O content was positively related with the area ratio of the spectral component centered around 950 cm⁻¹ (Q¹ component), and the CaO content was negatively related with the area ratio of the spectral component centered around 1150 cm⁻¹ (Q³⁴ component); these observations were made according to the partial correlation coefficients of 0.725 (p value < 0.001) and −0.553 (p value < 0.001), respectively.

During the preparation of the celadon glaze samples, we allowed for independent variations, both in firing temperature and in chemical composition, to reveal their individual effects when Raman spectroscopy was applied. In most previous studies, Raman has been applied in real ceramic samples to analyze the effect of firing temperature or composition on the I_P value without controlling either. Thus, the deduced dependence of I_P value on the firing temperature or on the composition is susceptible to bias [14]. One recent study used celadon fragments made of one formulation, with variation only in the firing temperature, to deduce its relationship with the I_P value [13]. This experiment obviously achieved more precise control of the temperature, but was limited by its formulation to discussing the relation between composition and I_P value. In addition, the composition of the celadon may have varied under different temperatures due to diffusion, evaporation, and other complex chemical reactions during the firing process. Therefore, the interaction effect of temperature and composition could not be completely isolated; hence, the estimation based on these samples could be vulnerable to inaccuracy. Compared with these studies, the current study provided a good opportunity to reveal the individual effects of firing temperature and composition on Raman parameters.

Contrary to previous studies that reported conflicting evidence on the positive relation between the firing temperature and the I_P value of celadon glaze [13], we found that the positive correlation was only valid for samples with low contents of K₂O and CaO, while it was invalid for the other groups and for the overall samples. This inconsistency could be due to failure to control the interference of the composition with the effect of the temperature, which was the case for most previous studies [3,4,6]. Pu’s study [13] attempted to clarify this issue in samples with uniform compositions. Specifically, the contents of K₂O and CaO were about 3.37% and 9.22%, on average, respectively. This formulation fell into the category of LKLC in our study, making his finding of a positive relation consistent with ours. For the overall samples with large variations in composition, the insignificant relation between the I_P value and the firing temperature is supported by Bo’s study [6], in which the authors applied the I_P value to a set of samples with large variations in composition.

A negative relation was detected between the contents of CaO and K₂O and the I_P value. Theoretically, this could be explained by the fact that the introduction of alkaline or alkaline-earth cations to silica induces depolymerization of the silicon–oxygen network to a certain extent [18]. As reported previously, the atoms of Ca and K have different effects during the fluxing process [19]. We found that the regression coefficients of the I_P value on the K₂O content and the CaO content were −9.645 and −5.332, respectively, suggesting that the K₂O has greater strength in terms of modifying the glassy network.

We also identified the individual effects of K₂O and CaO on the shaping of the stretching peaks of celadon glaze samples. Particularly, the K₂O content was shown to be positively related with the area ratio of the spectral component centered at ~950 cm⁻¹, which was consistent with previous study based on medieval-like glass samples [14]. This could be explained by the fact that adding K₂O to a glassy silica network would increase the O:Si ratio and would cause the remaining silica tetrahedra to form chains, rings, or compounds [20]. As is consistent with the previous study [13], we also found that the CaO content was negatively related with the area ratio of the spectral component centered at ~1150 cm⁻¹. The theoretical reason could be that introducing CaO allowed free oxygen to destroy the Si–O linkages, which dissociated sheet-like entities to form chain entities during the melting process.

On the Raman spectrum, the bending peaks were not significantly affected by either the firing temperature or the chemical compositions, which was consistent with previous studies on ancient ceramics. It is noteworthy that our analysis was conducted with simulated samples of ancient Chinese celadon, characterized by a CaO content of 6%–~15% (in wt%), a K₂O content of ~2%–6% (in wt%), and a firing temperature range of 1180–1250 $℃$. Applications of our results beyond these scopes should be carried out cautiously.

5. Conclusions

In summary, we revealed that a positive effect of firing temperature on I_P value exists in celadon with low K₂O and low CaO contents. In addition, both K₂O and CaO are negatively related to the Raman polymerization index in celadon glaze samples. Our finds could help to non-destructively clarify the fabrication techniques of ancient ceramics, determine their provenance and classification, recognize their authenticity, and even improve their preservation.