European ceramic technology in the Far East: enamels and pigments in Japanese art from the 16th to the 20th century and their reverse influence on China HAL Id: hal-02797126 https://hal.sorbonne-universite.fr/hal-02797126 Submitted on 5 Jun 2020 HAL is a multi-disciplinary open access archive for the deposit and dissemination of sci- entific research documents, whether they are pub- lished or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L’archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d’enseignement et de recherche français ou étrangers, des laboratoires publics ou privés. European ceramic technology in the Far East: enamels and pigments in Japanese art from the 16th to the 20th century and their reverse influence on China Riccardo Montanari, Nobuyuki Murakami, Philippe Colomban, Maria Alberghina, Claudia Pelosi, Salvatore Schiavone To cite this version: Riccardo Montanari, Nobuyuki Murakami, Philippe Colomban, Maria Alberghina, Claudia Pelosi, et al.. European ceramic technology in the Far East: enamels and pigments in Japanese art from the 16th to the 20th century and their reverse influence on China. Heritage Science, Springer, 2020, 8, pp.48. �10.1186/s40494-020-00391-2�. �hal-02797126� https://hal.sorbonne-universite.fr/hal-02797126 https://hal.archives-ouvertes.fr Montanari et al. Herit Sci (2020) 8:48 https://doi.org/10.1186/s40494-020-00391-2 R E S E A R C H A R T I C L E European ceramic technology in the Far East: enamels and pigments in Japanese art from the 16th to the 20th century and their reverse influence on China Riccardo Montanari1* , Nobuyuki Murakami2, Philippe Colomban3, Maria Francesca Alberghina4, Claudia Pelosi5 and Salvatore Schiavone4 Abstract The production of Japanese enamels for porcelain decoration was thought to have originated from the direct and exclusive influence of Chinese potters who moved to Japan during the chaotic Ming to Qing dynastic change in 1644. Recent systematic studies have identified, for the first time, the crucial influence of Jesuit missionaries on pigment and enamel production in Japan from the late 16th-century. In particular, such first encounter laid the foundation for the continued influence exerted by European technology on Japanese art throughout the centuries. The present study has further identified European enamels used for the decoration of polychrome wares fired in Arita, the porcelain production center of Japan. This continued exchange not only marked the Edo period, but also extended into the twentieth century. For the first time, the lack of written records regarding the use of western pigments for enamel production caused by the persecutions of European and Japanese Christians has been overcome in the work herein presented. The nature of the imported materials has been firmly identified and characterized. The analytical results (EDXRF and Raman) have finally revealed how western technology and materials not only kept influencing Japanese art during the isolation (sakoku) period, but also accompanied the strong westernization process that marked Japa- nese history from the late nineteenth century. Moreover, the significant reverse influence of Japanese-made enamels on Chinese polychrome porcelain production in the late Qing and twentieth century has been fully identified for the first time. Furthermore, results show that the shift of the Pb mode of lead antimonate (Naples Yellow) is affected by the firing temperature for enamel decoration, and that this characteristic, along with the chemical composition, enables the identification of the origin and manufacture period of the yellow enamel. Keywords: Porcelain, Enamel, Pigment, Painting, Japan, Jesuit, Seminario, China, EDXRF, Raman © The Author(s) 2020. This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. 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Introduction and historical context The production of overglaze enamels in Japan was long thought to have originated from the direct and exclu- sive influence of Chinese potters in the mid seventeenth century [1, 2] when the collapse of the Ming dynasty caused many of them to flee to Japan to find new profit- able markets for their own survival. Yet, recent system- atic studies on the origin of the materials employed for polychrome decoration identified, for the first time, the technological exchange that occurred between Jesuit missionaries and Japanese painters and potters from the late sixteenth century [3, 4]. In particular, the Euro- pean Renaissance practice of using the same coloring agents both for paintings and ceramics was unquestion- ably confirmed by the matching compound detected on a Open Access *Correspondence: ckrm97@yahoo.com 1 Independent Researcher, Expert Witness, Rome, Italy Full list of author information is available at the end of the article http://orcid.org/0000-0002-0228-6052 http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/publicdomain/zero/1.0/ http://creativecommons.org/publicdomain/zero/1.0/ http://crossmark.crossref.org/dialog/?doi=10.1186/s40494-020-00391-2&domain=pdf Page 2 of 17Montanari et al. Herit Sci (2020) 8:48 coloured porcelain and a European style painting created by a Japanese painter who studied at the Jesuit Seminario under the direction of the Italian Jesuit painter Giovanni Cola from 1583 [4]. The production of sacred and secu- lar images based on models imported from Europe, be it prints, engravings or paintings, involved the use of European pigments that did not exist in Japan at the time [3–6]. These new pigments also marked Chinese enamel production from the early eighteenth century, after Jes- uit missionaries were ordered by the Kangxi Emperor in 1695 to establish a glass workshop in the Palace to repro- duce the enamels of western origin that had strongly impressed him [7, 8]. Recently, Raman analyses have con- firmed the use of European enamel precursors at the end of Kangxi reign as mentioned in historical records [9, 10]. This pattern of influence had actually originated in Japan in the late sixteenth century [3, 4]. Additional evidence comes from Naito Tokuen Johan [11], a Christian samurai and close friend of Takayama Ukon, who supported the establishment of a glass workshop in the painting Semi- nario built by the Jesuits in Arie in 1595 under the super- vision of Giovanni Cola [11]. The Jesuit Seminario was attended by Japanese and Chinese painters eager to learn European oil painting techniques [12]. The imported compounds employed for such purpose were scarce and very expensive [6], so their use was strictly allowed to those having trained under the direct supervision of Giovanni Cola himself. In particular, tin and antimony were important elements used in Renaissance Europe for enameling of majolica [13–16], Limoges metal wares [17], and for preparing painting pigments [18, 19]. Both end-members of pyrochlore solid solutions (lead–tin yel- low and lead antimonate yellow) as well as more complex solid solutions had been largely used since Roman times [20–22]. These same pigments have been detected on the famous Painting of the Madonna with the Infant Jesus and Her Fifteen Mysteries (1620  s, Japan) [5] and on the rare mukozuke dish bearing the Japanese mark ‘Kan’ei Nen Sei’ (made in the Kan’ei period, that is 1624–1644) [3]. Those instances have provided the definitive proof that the first phase of technological exchange between Europe and Japan started in the late sixteenth century, and that it continued until the final expulsion of all Chris- tians by the Tokugawa Shogunate in 1639 as a result of the strictly enforced persecutions, with no surviving doc- uments relating to the Jesuit presence and the early inter- action with the Japanese. This study has proven, for the first time, how such first technological exchange between Jesuit missionaries and the Japanese in the sixteenth century laid the foundation for the continued influence exerted by Europeans on Japanese applied arts (porcelain, prints, and paintings) throughout the Edo period (1603– 1868) and into the twentieth century. We report here a non-destructive analysis carried out by X-Ray Fluorescence (ED-XRF) and Raman spec- troscopy in order to get more information on the use of these ceramic pigments, thus overcoming the daunting issue of the lack of written records regarding the use of western pigments and/or western technology for enamel production. Shards of polychrome decorated porcelains fired in Arita, the porcelain production center of Japan, dating from the nineteenth and twentieth century, were analyzed with the aim of identifying the coloring agents employed for such production. The results have finally provided a definitive answer, revealing how western tech- nology and materials not only kept influencing Japanese art during the isolation (sakoku) period, but also accom- panied the strong westernization process of the country that marked Japanese craft and industry from the late nineteenth century. Materials and methods Analyzed shards All analyzed shards were provided by the Arita Museum of History, Arita, Saga Prefecture, Japan, and were mostly excavated at the Aka-e machi site (enamellers’ quarter) located in the Uchiyama area of Arita, where all enam- ellers had been moved by the Nabeshima clan in the late 1650s in order to improve the production process through better labor organization [4]. The shards provide crucial information regarding the coloring agents and enamel preparation techniques employed when the pres- ence of western countries increased significantly and the Tokugawa shogunate was about to collapse. Characteris- tics are summarized in Fig. 1. XRF spectrometer: experimental and measurement parameters The employed XRF portable instrument consists of a min- iature X-ray tube system (Amptek, X-123 SDD, Mini-X X-ray tube, USA) which includes the X-ray tube (max volt- age of 40  kV, max current of 0.2  mA, target Rh, collima- tor 1 or 2  mm), the power supply, the control electronics and the USB communication for remote control; a Sili- con Drift Detector (SDD) with a 125 to 140 eV FWHM @ 5.9  keV Mn Kα line Energy Resolution (depends on peak- ing time and temperature); 1 keV to 40 keV detection range of energy; max rate of counts to 5.6 × 105 cps; software for acquiring and processing the XRF spectra. Primary beam and detector axis form an angle of 0 and 40 degrees respectively with the perpendicular to the sam- ple surface. Measurement parameters were as follows: tube voltage 35  kV; current 80 μA, acquisition time 100  s; no filter was applied between the X-Ray tube and the sample; Page 3 of 17Montanari et al. Herit Sci (2020) 8:48 Fig. 1 a Analyzed shards with underglaze and overglaze decoration. Kiln sites, production date and XRF or Raman measurement areas are given (the dimensions are here reported: Shard #7: 12 × 9 cm2; #8: 16 × 13 cm2; #9 diameter: ~ 9.8 cm; #10: 9.5 × 8 cm2; #11: 7 × 5 cm2). b Fracture sections showing the glaze-body interface of the #8, #9, #10, #11 analysed shards acquired by using portable optical microscopy (50 magnification) along the fracture lines without any sampling Page 4 of 17Montanari et al. Herit Sci (2020) 8:48 distance between sample and detector around 1  cm. The setup parameters were selected to have a good spectral sig- nal and to optimize the signal to noise ratio (SNR). Meas- urement data were processed using the factory provided data reduction DPPMCA software, which enables the acquisition, display, and control for Amptek signal proces- sors and allows the automatic peak recognition supported by manual peak selection and checking. The software fur- ther enables curve fitting based on chosen elements to ensure a match between the measured spectra and theo- retically predicted spectra calculated from fundamental parameters (FP). Finally, XRF spectra have been graphically provided by Origin Pro 8.5. Raman spectroscopy The micro-Raman analysis was performed through a Ren- ishaw InVia Raman Microscope (UK). The fragments were examined without any preparation. In order to make the fragment surface perfectly perpendicular to the laser path and to improve the focus, the shards were positioned on a clay base. Two exiting wavelengths were used: 532 nm and 633 nm. The diffused light was recorded in a backscattered geometry using a 50× objective at long focal distance, in order to obtain a measurement spot of about 4 microns in diameter. Spectra were managed by Wire 2.0 software, associated to the Renishaw instrument. Results and discussion The overglaze enameled shards analyzed in this study are characterized by the presence of coloring agents of Euro- pean origin. We will discuss the Raman and XRF data recorded on the different colored areas, yellow, blue, and green. Overglaze yellow enamels Raman analysis The Raman spectra detected on the nineteenth and twen- tieth century Japanese yellow enamels and on the seven- teenth century mukozuke dish are reported in Fig. 2. Naples yellow pyrochlore is a non-stoichiometric A2-xA’B2-y B’yO7-δ phase built with two sub-lattices, one of (big) A cations (A = Pb2+ in the case of Naples yel- low pigment), the second of (small, covalent bonded) cations (B = Sb, Sn, Fe, Zn, Si, Zr…) forming tetrahedral and octahedral entities sharing some oxygen atoms [23, 24]. B cations are easily oxidized/reduced and thus the formula and oxygen stoichiometry depend on the firing atmosphere. Due to the high mass of lead, the Raman signature show a characteristic strong peak arising from the Pb translational mode at low wavenumber, ranging from ~ 125 to ~ 140  cm−1 as a function of the composi- tion/structure [13–15, 17, 25]. Studies of Sn–O and Sb-O end members have allowed the identification of the Sn–O and Sb-O stretching modes (stretching modes are strong in Raman spectroscopy) at ca. 450 and 505 cm−1 respec- tively [17]. Thus differentiation between Sn-rich and Sb-rich Naples Yellow is obvious from their Raman spec- trum: Sb-rich pigment shows two strong peaks at ca. 130 Fig. 2 Yellow enamel Raman signature: a Shard #7 yellow enamel (1894); b Shard #9 yellow enamel (1932–1945), two spectra are reported to show the good reproducibility of the measurements acquired on different yellow spots; c mukozuke dish Naples Yellow (1630s) [3] Page 5 of 17Montanari et al. Herit Sci (2020) 8:48 and 505  cm−1, while Sn-rich pigment shows a spectrum with peaks at ~ 130, 325, 450 and 505 cm−1 [17]. As shown in Fig.  2, the spectra recorded on the yel- low decorations of shards #7, #9, and the previously ana- lysed seventeenth century mukozuke porcelain, all show a strong ca. 130–140–505  cm−1 doublet, characteristic of a Sb-rich Naples Yellow pyrochlore. However, the three yellow enamels feature different wavenumber positions of the strong Pb mode, namely 135, 141 and 130  cm−1, and all prove to be a shift higher than the uncertainty of the measure. The lowest value detected on the mukozuke dish, 130  cm−1, corresponds to a firing temperature in the range of 900–1000 °C according to Sakellariou et al. [16]. Such temperature value is consistent with the firing tem- peratures that characterize lead antimonate yellows in Renaissance Italy [13, 16, 18, 26–30]. XRF analysis XRF spectra recorded on yellow colored areas show strong Pb peaks and medium Si peaks as expected for lead-based overglaze enamels. The Pb-Sb yellow detected on shard #7 (Fig.  3a) and the Pb–Fe–Sb–(Zn) yellow detected on shard #9 (Fig. 3b) both bear an enamel matrix consisting of the ternary system Pb–Si–K. Such matrix composition, along with the presence of antimony, strongly points to the recipe reported by Takamatsu in 1878 [31]: Shiratama (PbO, SiO2, K2O) and Tojirome, an antimony-based compound, are listed as the main components to be used for yellow decoration “…nearly pure antimony… also called Toshi- rome…is used as a yellow enamel with Shiratama and other bodies, whereby oxides of antimony and lead are formed which give the yellow colour”. This description confirms that the preparation of the antimony-based enamel differs from the European Renaissance recipe. The Japanese yellow color is not the specific compound obtained through calcination as the traditional European method employed for Naples Yellow required [16, 18], but it appears to be basically a by-product of the reaction between the mixed reagents. Comparison with the spec- trum of the Italian Renaissance Naples Yellow (lead-anti- monate yellow) detected on the famous mukozuke dish dated 1624–1644 (Fig.  3c) [3] clearly shows that the late Renaissance enamel consists instead of a Pb–Si matrix with no significant amount of potassium: the yellow on the mukozuke dish perfectly matches the recipe for Giallo de’ Vasari (Potters’ yellow) published by Valerio Mariani in 1620 in the treatise Della Miniatura [13, 14]. The Pb–Cr yellows detected on shards #8 and #10 (Fig.  4a, b) prove to belong to the Cr-based enamels developed in Europe in the early nineteenth century. The use of Cr-based enamels for ceramic decoration was emphasized by Vauquelin, the discoverer of the element chromium [32]. These new findings are consistent with the previous detection of a Cr-based yellow enamel on a porcelain cup produced in Arita in the second half of the nineteenth century [4] (Fig.  4c), thus confirming the Fig. 3 Representative XRF spectra recorded on yellow coloured areas: a Shard #7 Pb-Sb yellow (1894); b Shard #9 Pb–Fe–Sb–Zn yellow (1932–1945); c previously analyzed mukozuke dish Pb-Sb Naples Yellow (1630s) [3] Page 6 of 17Montanari et al. Herit Sci (2020) 8:48 incorporation of such chromophore in the Japanese por- celain industry in the early-to-mid nineteenth century. Blue coloring agent and overglaze enamels The XRF spectrum of the underglaze blue pigment detected on shard #7 shows a manganese to cobalt ratio (Mn/Co < 1) incompatible with the use of a natural and pure Asian cobalt ore [33, 34]. This demonstrates that the chromophore consists of a mixture of natural cobalt imported from China and a synthetic blue material devel- oped in Europe (Fig. 5a). It is interesting to note here that the practice of mixing different grades of blue materials in Japan started in the mid-seventeenth-century when trade with Europe became the main drive of the porcelain industry in Arita: western taste demanded heavy decora- tion and Japanese potters needed to save up on material cost in order to improve profitability [4]. The XRF spectrum recorded on the overglaze blue dec- oration of shard #8 (Fig.  5b) shows a chemical composi- tion consistent with the European smalt-based enamel characterized by the elements Ni–Fe–As in association with Co. European sources of cobalt are vein of arsenates secondary deposits, while Asian cobalt sources are pri- mary deposits rich in Fe and Mn [35]. The XRF spectrum recorded on shard #9 shows instead the use of an over- glaze blue enamel based on a compound of Co and Zn (Fig. 6a). The results unquestionably prove that starting from the second half of nineteenth century and well into the twen- tieth century, Japanese potters gradually replaced most of the low-grade natural cobalt ores (rich in manganese and iron) imported from China and the smalt-based over- glaze blue enamel imported from the Old Continent with Co-based synthetic pigments of European origin char- acterized by a higher coloring power and less sensitiv- ity to firing atmosphere. This same type of blue material appears to have been consistently used until the present day as testified by the analysis carried out on a contem- porary polychrome porcelain cup of high artistic value fired in Arita (Fig. 6b). Overglaze green enamels Visual inspection of the green colored shards herein analyzed strongly points to the intentional use of differ- ent compounds aimed at achieving various chromatic effects. Besides the expected use of copper ions dissolved in the glassy matrix for the traditional green color [7], a Cu–Cr-containing enamel was detected on shard #10 by XRF (Fig. 7a). Such instance is in perfect agreement with the recipe published in 1869 by Thomas Salter in Field’s Chromatography or Treatise on Colours and Pigments as Used by Artists: the author lists a Cu-Cr pigment that “… may be prepared by several methods”. Furthermore, the light-green enamel analyzed on shard #11 (Fig.  7b) proves to originate from the mixture of Sb and Cu. In particular the color is obtained by adding Cu Fig. 4 Representative XRF spectra recorded on yellow area: a Shard #8 Pb–Cr yellow (1868–1912); b Shard #10 Pb–Cr yellow (1850–1900); c porcelain cup produced in Arita in the second half of the 19th century Pb–Cr yellow 4 Page 7 of 17Montanari et al. Herit Sci (2020) 8:48 to the recipe for the Pb-Sb yellow detected on shard #7 (Fig. 3a). Noteworthy is to mention here the Renaissance recipe by Cipriano Piccolpasso, who listed in his “Li Tre Libri dell’Arte del Vasaio” (The Three Books of the Pot- ter’s Art) in the mid-sixteenth century, a “mixed” green pigment consisting of a mixture of Cu, Pb and lead anti- monate yellow [36]. Such record well traces the Italian origin of the later-developed northern European recipes that spread in the Far East in the nineteenth century as here demonstrated. Naples yellow pigment: a tracer of Europe‑Japan technological exchanges Preparation procedures As previously presented, the Pb-Sb yellow enamel detected on shard #7 (Fig.  3a) and the Pb–Fe–Sb–(Zn) yellow detected on shard #9 (Fig.  3b) both bear a Pb– Si–K matrix. This enamel composition is perfectly con- sistent with the recipe reported by Takamatsu in 1878 [31], therefore the preparation of the Pb–Sb and Pb–Fe– Sb–(Zn) compounds clearly differs from the calcination process required for the production of the European Renaissance Naples yellow. Moreover, no K was detected on the mukozuke dish (Fig.  3c) as expected for a lead antimonate compound prepared according to Valerio Fig. 5 Representative XRF spectra of recorded on blue areas: a Shard #7, underglaze blue pigment (1894); b Shard #8 (1868), overglaze Pb-containing blue enamel Fig. 6 Representative XRF spectra recorded on blue areas: a Shard #9 (1932–1945), lead-based overglaze; b Contemporary overglaze lead based blue enamel Page 8 of 17Montanari et al. Herit Sci (2020) 8:48 Mariani’s recipe for Giallo de’ Vasari (Potters’ yellow) published in the treatise Della Miniatura (1620) [18]. The implication is clear: the composition of the Japanese yel- low enamels differ dramatically from the common Ital- ian Renaissance recipes. The Renaissance yellow bears the fluxing agent NaCl, while the nineteenth-century Japanese yellows show the employment of a K-based flux, thus proving to belong to the group of contemporary antimony-based yellows developed in northern Europe [26, 37] on the basis of the original Italian process pub- lished by Passeri in 1758. The French scientist Fougeroux de Bondaroy (1769) was the first to have modified the process by adding potassium alum, and the other north- ern European recipes followed suit [26, 37]. The results perfectly fit into the trade picture of the nineteenth century, when new materials were being imported into Japan from northern Europe by the Dutch [4, 31, 38]. As a consequence of the isolation policy enforced by Tokugawa Shogunate, European materi- als available for porcelain production and paintings differed over the centuries. The mukozuke dish was dec- orated with a Renaissance yellow enamel of Italian ori- gin imported by the Jesuits in the early 1600s, while the nineteen-century porcelains were enameled with a yellow color based instead on the recipes developed in northern Europe in the nineteenth century. Yet the Japanese created their own path and changed the actual production process of the coloring agent. European recipes required the calcination of a mixture of antimony oxide and lead oxide to achieve a stable Naples Yellow compound to be embedded in the NaCl fluxed matrix [16, 18, 39], as consistently detected on the mukozuke dish. The Japanese method involved instead the use of different bodies providing a Pb–Si–K matrix to which an antimony compound, pure antimony from Iyo province [31], was then added. No previous calcination was carried out, thus leading to different enamel char- acteristics in terms of formed phases and reagents stoi- chiometry. Raman spectra (Fig. 2) provide further crucial information as to the firing temperatures of the anti- mony-based compounds, thus enabling the identification of their geographical area of origin and, along with XRF compositional data, their period of production. The Raman signature of the pyrochlore solid solution In order to fully understand this point, we have to con- sider that lead antimonate belongs to the family of com- pounds with the ideal pyrochlore structure having the general formula A2B2O6O’ [13, 16, 27, 28, 40, 41]. B-O bonds are crucial to the cohesion of the crystal and a reg- ular BO6 polyhedron entails a more-distorted AO8 poly- hedron and vice versa [40, 41]. The (B–O) force constants are six to eight times stronger than those of f(A–O) and f(A–O’) [40, 41]. Firing temperature, stoichiometric ratio, and small distortions of the pyrochlore structure strongly affect the Pb mode of the A2O’ lattice. Yet even a significant perturbation of the A4O’ network has a weak influence on the BO6 network and overall rigidity of the structure [40, 41]. Therefore, from a vibrational stand- point, the two networks appear, on first approach, to be energetically independent [41]. The implication is clear: the firing temperature for enamel decoration affects the Raman wavenumber of the Pb mode to such a greater extent than the compositional base of the matrices in which the chromophore is embedded or the respective molar ratios. The lower the value of the diagnostic-peak wavenumber, the more stable the structure of the pig- ment owing to the increasing firing temperature [16]. It has been firmly demonstrated that as the firing tempera- ture increases, the peak shifts to lower wavenumbers: Fig. 7 Representative XRF spectra recorded on green area: a Shard #10 (19th 2nd half c.); b Shard #11 (19th 2nd half c.) Page 9 of 17Montanari et al. Herit Sci (2020) 8:48 134  cm−1 at 800  °C, 130  cm−1 at 950  °C, and 124  cm−1 at 1100  °C [16]. The peak at 130  cm−1 observed on the Naples yellow used to decorate the mukozuke dish (Fig.  2c) matches the reported data perfectly, confirm- ing an Italian Renaissance lead antimonate yellow fired at 900–1000 °C (‘Feu de moufle’). A firing temperature in the range of 900–1000 °C is incompatible with either the ceramic technology at Jingdezhen where overglaze enam- els were fired at 700–800 °C [42, 43] or a Chinese enamel- on-metal technology with enamels fired at 600–700  °C [44, 45]. The latter, in particular, employs additional flux- ing agents such as CaF2 or even Bi2O3 [44] that lower the processing temperature, thus relying on a thermal-treat- ment duration which clearly differs between China and Europe in terms of kiln technology and heating rate. The values of the diagnostic-peak wavenumbers observed on Chinese wares of any media, be it porcelain or metal, from any period and recipe, that were deco- rated with a lead antimonate yellow enamel [42, 44] fall within the range 136–142  cm−1 [42, 44]. They therefore fit into the firing-temperature range associated with both technologies in China, namely 600–800  °C [42–45]. As a consequence, a Chinese origin and firing of the yellow enamel is to be ruled out on the basis of such experimen- tal evidences. The strong peaks at 135  cm−1 and 141  cm−1 detected on the Japanese nineteenth-century Pb–Sb and Pb–Fe– Sb–(Zn) yellows (Fig.  2a,b), unequivocally point to a fir- ing temperature in the range of 700–800  °C [16, 42] as confirmed by kiln practice for the period in Arita. To conclude, based on the evidence discussed so far, the implication is very clear: the firing temperatures and chemical compositions of the Chinese Naples Yellows [42–46], be it on metal or ceramic, and the Japanese nine- teenth century Naples Yellow, all differ dramatically from the Naples yellow of European origin that was detected on the mukozuke dish fired in the late Renaissance period (1630s). The latter shows a Raman signature consistent with the firing temperature of 950 °C as identified identi- fied by Impey for the firing of Arita wares in the early Edo period [47, 48], as well as the firing temperature needed in Renaissance Italy to obtain a brighter and richer anti- mony-based yellow color [16]. The results point to a fir- ing process the mukozuke dish underwent in western Arita, most likely at the Yanbeta kiln, under the super- vision of European missionaries in the 1630s, before the final expulsion of all missionaries in 1639. Historical recipes and scientific evidence: the connections Provenance and use of antimony Documentary evidence and recent studies confirm that antimony was imported into Japan during the seven- teenth century [4, 31, 38, 48, 49]. In particular, a Dutch record for the year 1690 mentions the import of anti- mony into Japan as specifically needed for the decora- tion of porcelain wares [48, 49]. This instance is a highly significant one as Dutch traders knew the pigments being exported very well, considering that those same pigments, that is, lead-antimony and lead–tin yellows, started being imported into China from Europe around the same period, after the glass workshop had been established in the Palace in 1695 as ordered by the Kangxi Emperor to Jesuit missionaries [8, 42, 46, 50, 51]. In fact, Teodorico Pedrini (a Lazarist), who arrived in China with the painter Matteo Ripa to work at the court of the Emperor Kangxi, petitioned Rome in 1711 for the sup- ply of antimony (antimono non preparato) and enamels (smalti) needed for the production of new colors at the imperial workshop [8]. The missionaries were focusing on the preparation of new enamels, such as lead–tin yellow, lead-antimony yellow, arsenic-white and pink, that would enrich the Ming ceramic palette based on the traditional transition metals that Jingdezhen potters had been using for porcelain decoration until the Qing dynasty [8, 42, 46, 50, 51]. Moreover, the Dutch record mentioning anti- mony in 1690 triggered the suggestion [48] that antimony may have been the coloring agent used by Kakiemon in the late seventeenth century to produce the classic wares that took Europe by storm. From a compositional standpoint, the chemical ele- ments detected on the lead-iron-antimony yellow on shard #9 (Fig.  3b) offer, for the first time, crucial infor- mation regarding the actual recipe that formed the basis of Japanese porcelain decoration in the nineteenth and twentieth century. The presence of Fe, K, Zn, Sb and Pb strongly points to the recipe developed by Louis- Alphonse Salvetat at Sèvres in the mid-nineteen century. A Fe-based enamel characterized by the addition of Sb and Zn is listed in Leçons de Céramique published by Sal- vetat in 1857: “Fondant 880, Fleurs de zinc 35, Oxide de fer hydraté jaune 70, Antimoine diaphorétique 15”. Noteworthy is that the French recipe well matches the chemical composition of the yellow enamel detected on shard #9: the Arita enamel is a traditional Fe-based yel- low with the addition of Sb, and Zn in a Pb–Si–K based matrix (Shiratama and other bodies as described by Takamatsu). The Raman spectrum (Fig.  2b) has confirmed the nature of the compound acting as coloring agent, and has also shown the different stoichiometry of the reagents and the different firing temperature as compared to Euro- pean kiln practice. The significant presence of Zn is clearly the result of the influence of Salvetat’s method. Its addition, as also described by Theodore Deck in La Faïence published in 1887, helped obtaining different shades of an opaque Page 10 of 17Montanari et al. Herit Sci (2020) 8:48 yellow in combination with Sb and Pb. Salvetat further explains in Leçons de Céramique how the use of Zn helps achieving a brighter yellow. Japanese potters appear to have followed such instructions to obtain a bright and opaque yellow for porcelain decoration. This new enamel also reveals a very interesting transi- tion from the Japanese traditional Fe-based yellow to the new Sb-Zn-containing European recipe. A clear instance of this change is represented by the Nabseshima shard (1690–1730) (Fig.  8a, b) and the Ko-imari Cup (1770– 1790) (Fig.  8c, d) as compared to the shards analyzed in this work. The translucent Pb–Fe-based yellow enamel employed on the highly traditional Nabeshima shard and Ko-Imari cup appears to have been consistently used from the mid-seventieth century, after the Jesuits had all been expelled from Japan, and throughout the eighteenth century. Japanese potters’ practice of yellow enamelling with the translucent iron-based color in the eighteenth century is also reported in the book of recipes attributed to Johann Gregorius Höroldt (director of the Meissen manufacture) and dated to 24 December 1731: the “Yel- low in the Japanese manner” is listed as consisting of iron compounds, contrary to the opaque Meissen yellow enamel based on lead antimonate [52]. Basically, Japanese potters ended up modifying their traditional translucent Fe-based recipe with minor addi- tions of Sb and Zn to make it brighter and opaque. It appears very clear now how the transition must have been gradual and possibly smooth in terms of techno- logical innovation as with other forms of applied arts. The same kind of approach emerges from ukiyo-e prints, where the incorporation of new synthetic colors of Euro- pean origin proved gradual, selective, and coexisted with Japanese traditional practice [53]. The technological implications are very significant: the Renaissance opaque yellow enamel was based on a com- pletely new and unknown technology that required Jesuit supervision in the first phase of enamel development in Japan in the 1630s, while the nineteen-century enamels were obtained by modifying the European methods on the basis of the Japanese established local tradition. The Japanese way developed by adapting European recipes to Japanese practice. It appears pretty clear how such approach led to the modification of the European reci- pes: the lead-antimonate yellow became the result of a mixture of compounds with no previous preparation by calcination; and the innovative incorporation of limited amounts of antimony and zinc into the traditional trans- lucent Fe-based yellow helped making it brighter and opaque. More details on the effect of the use of zinc in yellow enamels for porcelain decoration is revealed by Alexan- dre Brongniart in the treatise Colouring and Decoration of Ceramic Ware, published in 1898, where the author says “Oxide of zinc enters into the composition of greens, yellows, yellow-browns and blues…Oxide of zinc…devel- ops qualities necessary for the beauty of certain colours”. The use of zinc as an opacifier belongs to the Euro- pean tradition as also testified by Salvetat in Leçons de Céramique. European materials for painting and ceramics The continued but very limited availability and circula- tion of European lead-based yellow chromophores in Japan is further clarified by the surviving early-seventi- eth-century painting depicting The Madonna with the Infant Jesus and her Fifteen Mysteries: the pigment lead– tin yellow, unknown in Japan, was detected on the cen- tral inscription in Latin characters (romaji) “LOWADO SEIA O SANCTISSO SACRAMETO” [5]. This specific pigment belongs to the same family of Naples Yellow, the lead-antimonate enamel detected on the famous muko- zuke dish fired in the Kan’ei period (1624–1644). Noteworthy is to mention here that along with imported pigments and Japanese traditional coloring agents, flaxseed oil, a vegetable drying oil of European origin, unknown in Japan, not only was detected on the painting The Madonna with the Infant Jesus and her Fif- teen Mysteries, but also on the western style screen Map of the World and Famous Cities (early seventeenth cen- tury), as the binding medium [5, 54]. This crucial instance has led Oka to emphasize the influence of Western tech- nology on painting production, and to identify the Jesuit Seminario as the source of the imported materials [54]. Such unrecorded use of Western materials is perfectly consistent with a period of strict enforcement of anti- Christian edicts by the Tokugawa Shogunate [3, 12], with no chance for any written records mentioning any direct interaction with the missionaries to survive. Unfortu- nately, the yellow color on the screen Map of the World and Famous Cities was not analyzed. Porcelain and paintings: one coloring agent for both productions Additional important confirmation comes from the Yan- beta shard previously studied (Fig.  9) [4]: the composi- tion of the green enamel analyzed on the shard perfectly matches the green pigment detected on the early-seven- tieth-century screen Western Kings on horseback [55]. In terms of technological implications, an early use of a Cu– As–Zn based green pigment has been clearly detected on the works by the sixteenth-century Italian painter Ste- fano Sparano [56]. Once again, the practice of using the same materials for paintings and ceramics is of European origin and does not belong to Japanese tradition. Page 11 of 17Montanari et al. Herit Sci (2020) 8:48 Fig. 8 a, b Nabeshima Shard (1690–1730) and Pb–Fe yellow enamel XRF spectrum; c, d Ko-Imari cup (1770–1790) and Pb–Fe yellow enamel XRF spectrum Page 12 of 17Montanari et al. Herit Sci (2020) 8:48 Persecutions and closure of the country European technology unknown to the Japanese was still available during the fierce persecutions that started in 1614, but on a very limited basis. Therefore, the overall analytical evidence confirms that the imported materi- als influenced color decoration on paintings and ceram- ics until the final expulsion of all Christians in 1639. The sakoku (closed country) policy established by the Toku- gawa Shogunate led to the strict control of anything that entered the country, and trade with Europe ended up being monopolized by the Dutch and the Chinese in Dejima, thus ending the phase of spontaneous westerni- zation of the applied arts that had started in the mid-16th century thorough the effort of Jesuits missionaries. Blue coloring agents Smalt: provenance and use Of particular interest is also the case of the overglaze blue enamel, the glass rich in potassium and colored by cobalt oxide, used in Europe since the fourteenth century for paintings and ceramics alike [57–60]. This blue pigment, also named smalt (saffre in French, smalto in Italian), has been detected on a hand-colored Japanese Buddhist print dated to the late 16th century [61], and on ukiyo-e paint- ings from the seventeenth to the late eighteenth cen- tury [38]. Recent systematic studies have demonstrated that smalt had initially been imported into Japan by the Jesuits for porcelain decoration in the late Kan’ei period (1624–1644), thus resolving the long-standing issue of the origin of the material [4, 62]. Afterwards the Dutch monopolized the trade [38]. From the Kanbun era (1661– 1673) the imported material was also employed on ukiyo- e paintings [38]. Noteworthy is that there are no earlier examples of the use of smalt in the Asian paper or silk painting tradition [38], so Japan appears to have been the first country where the material started to be used under the supervision of Jesuit missionaries in the late sixteenth century. This pioneer use of imported European materials proves perfectly consistent with the detection of lead- antimonate yellow on the rare mukozuke dish (Fig.  2c, 3c), of lead–tin yellow on the painting The Madonna with the Infant Jesus and her Fifteen Mysteries, and of flaxseed oil on both The Madonna with the Infant Jesus and her Fifteen Mysteries and the western style screen Map of the World and Famous Cities. No wonder we find smalt on ukiyo-e works from the latter half of the seventieeth century: the supply of the material, as for the case of porcelain production [4], had stabilized at the time by means of the trade with the Dutch, who, to cope with the high demand, established a production facility in Holland [4, 38]. The pigment innovation of the late 16th century, as testified by the hand-colored Buddhist print [61], kept showing strong roots in the artists’ creative approach. The detection of smalt on ukiyo-e paintings is very significant as ukiyo-e repre- sented a new form of art that shaped popular culture during the Tokugawa Shogunate. Once again, as for the craze for anything European (Namban) that took Japan by storm in the Momoyama period (1568–1603), European innovations kept inspiring new experimen- tation that shaped the artistic forms of the whole Edo period (1603–1868). Paintings and enameled porcelains were expensive commodities; therefore it makes perfect sense to have found the imported materials on works reserved for the wealthy. Significant instances of the use of smalt by Japanese masters come from the seventieth-century painting Flowers and Rocks by Ogata Korin (1655– 1716) and the late-eighteenth-century Moonlight Rev- elry at Sagami Dozo by Kitagawa Utamaro [62]. In terms of pigment origin, full confirmation comes from the blue color analyzed on a Japanese votive painting dated 1682 [63]: the chemical composition of the pigment is Co–Ni–Fe–As, which, as expected, perfectly matches the composition of the European smalt-based enamel imported into Japan by the Jesuits in the late 1630s for overglaze blue decoration of por- celain wares [4]. It is worth noting here that the prac- tice of using the same coloring agents for paintings and ceramics belongs to the European technological tradition. Japan therefore established itself as the first country to have incorporated European Renaissance technology into traditional Far Eastern applied arts. Smalt, as for the case of Naples Yellow, lead–tin yel- low and arsenic-opacified white, will acquire a central role in the new opaque enamel palette developed at Fig. 9 Schematic of XRF signal of Cu, Zn and As elements recorded on shard # YB3 in a previous work [4] Page 13 of 17Montanari et al. Herit Sci (2020) 8:48 Jingdezhen (China) from 1720s for the decoration of imperial wares [7, 8, 42, 64, 65]. Foreign coloring agents in the late Edo period (eighteenth and nineteenth centuries) Ukiyo-e paintings were gradually replaced by woodblock prints, an inexpensive mass produced form of art. Pub- lishers needed to switch to less expensive and ready-to- use materials in order for the prints to be enjoyed by the public at large: Prussian Blue, a synthetic pigment devel- oped in the Old Continent in the early eighteenth cen- tury [66], started to replace smalt and coexist with native natural pigments from the early nineteenth century [67], as testified by masterpieces such as Doshoku Sai-e by the painter Ito Jakuchu (1716–1800) [68]. It is interesting to note here that smalt and Prussian Blue have been identi- fied as being part of the Kaishunsai paints, the pigments collected by the Nabeshima family in the early nineteenth century and stored in Takeo city, Saga prefecture [69]. Takeo city is located in the vicinity of Arita, where the production of blue-decorated porcelains was recently discovered to have developed in the late 1630  s on the basis of a smalt-based enamel imported by the Jesuits [4]. The Nabeshima family controlled porcelain produc- tion in Arita, and the clan’s crucial role became evident on the occasion of the organization and unification of the kilns that occurred in 1637 [70]. Such change was needed to exploit the full potential of the porcelain trade. So the presence of the pigments in the collection further testi- fies to the influence of European technology on art pro- duction in Japan throughout the Edo period. Comparison with China: smalt and European chromophores European technological influence on Chinese arts fol- lowed the exact same path established in Japan one cen- tury earlier. The Chinese, after the first technological exchange with the Jesuits in 1695 [7], started incorporat- ing new imported materials into their artistic practice: smalt, lead–tin yellow, lead-antimonate yellow, Pb-Sb- Sn yellow, arsenic white, Prussian Blue and new artificial pigments saw an extensive use in ceramics and paintings throughout the Qing dynasty and up to the present day [42, 64, 65, 71]. Contrary to the case of Japan, Jesuit mis- sionaries enjoyed imperial patronage in China and were free to exert their influence on the production of poly- chrome wares at Jingdezhen in the late seventeenth and early eighteenth century. In Japan the Jesuits were forced to hide when the young porcelain industry in Arita started developing the first overglaze enamels. There- fore the same gradual modification and incorporation of European recipes as identified in eighteenth-century China and late-nineteenth-century Arita, would have been impossible in the early seventeenth century when the fierce persecutions culminated in the final expulsion from Japan of all missionaries in 1639. The two painting and ceramic traditions, Japanese and Chinese, however, differed for the extensive use of smalt that characterized the former and that almost completely lacked in the latter [7, 47, 72–75]. European recipes for the global market: production innovations in the porcelain industry of Arita Domestic consumption of porcelain in Japan had spread by the late eighteenth century [76], yet the porcelain industry started to face a deep decline due to the reduced trade with Europe, kiln destructions by fire [76], and the fierce competition by the mass-produced Chinese cop- ies of Imari wares that had flooded the European market in the eighteenth century [73, 74]. Chinese traders were capable of taking full advantage of any business oppor- tunity arising in the Far East. In this highly competitive environment, kiln owners in Arita needed to devise new strategies to make the whole process less expensive and meet domestic and western taste. The development of new colors involved the use of synthetic pigments made in Europe: the present results show how such decision became a dominant factor in enamel production. A clear shift to the newly-developed and cheaper materials took place in the nineteenth century, after a predominance of the traditional coloring agents in the seventeenth and eighteenth centuries (transition metals), yet with the con- tinued import of the smalt-based blue enamel form the Old Continent. In particular Takamatsu describes the imported blue material from Europe in 1878 [31] by saying: “No certain information of the manufacture of this substance has been obtained at present. It is said that it may be prepared by fusing crude oxide of cobalt with a mixture of clay and alkalies, so as to form a kind of blue glass, or smalt. At present foreign smalt is largely used, being sold at a cheaper rate”. Takamatsu therefore records that the blue pigment, known in Japan as Hanakonjo, was being imported as a ready-to-use material, thus confirming that Japanese painters and potters had not yet established a local pro- duction and kept relying on the European supply until the early twentieth century [31, 77], as also demon- strated in this work. The continued use of imported smalt remained unchanged since the late 16th century, as tes- tified by the Japanese votive pictures and ukiyo-e paint- ings, up until the twentieth century [77]. Our results have also shown that the blue pigment employed in Arita from the late nineteenth century consisted of the newly devel- oped Co-based synthetic material of European origin that gradually replaced smalt for overglaze decoration, Page 14 of 17Montanari et al. Herit Sci (2020) 8:48 and low-grade natural-cobalt-ores for underglaze deco- ration (Fig.  5a, 6a). These findings, along with previous studies [3, 4], fully reveal that even though the Japanese had been exposed to European materials from the late 16th century, they didn’t succeed in mastering the tech- nology needed to reproduce them until the early twen- tieth century. This further explains why the very limited use of the scarce and expensive lead-based yellows dur- ing the Momoyama and early Edo periods suddenly stopped after the final expulsion of all Christians and Jes- uits in 1639. The Japanese were still in the earliest stage of enamel-firing experimentation and therefore needed a new chromophore to replace the unavailable Jesuit- related yellows (lead antimonate and lead–tin yellows). Yellow was the most difficult color to fix for Arita potters [70] and the issue was resolved by means of the cheaper and easier-to-fire iron yellow, likely through Chinese supervision. But the practice of replacing imported Euro- pean materials of unknown technology with Chinese pig- ments could not be successfully carried out in the case of smalt. The Japanese were not capable of reproducing the same coloring effect with any of the materials available to them at the time, locally or from China. This is firmly demonstrated by a previous study by Montanari et al. [4]: the polychrome decorated shard (1640–1650) excavated at the Naka-Shirakawa kiln-site (Fig.  10a, b) reveals the attempt to use a low-grade cobalt ore imported from China (commonly employed for underglaze blue deco- ration) to achieve an overglaze blue-green effect. The attempt failed as the low-grade cobalt ore was unsuit- able for overglaze decoration. It becomes undoubtedly clear that as soon as the Jesuits left the country in 1639, the technology to obtain smalt could not be reproduced, and the failed Naka Shirakawa attempt testifies to the tireless effort by Arita potters to find a way of replacing the imported blue material. Potters could not succeed in that task, and were therefore forced to keep relying on imports from Europe. Furthermore, the Naka-Shirakawa shard bears a Fe-based yellow enamel. The presence of both the ‘experimentally-failed’ overglaze blue-green enamel and the Fe-based yellow enamel on the same shard testifies to the frantic situation Arita potters were facing in the earliest stage of polychrome porcelain pro- duction right after Europeans had been expelled from the country in 1639. The shard is offering a glimpse of the period that followed immediately after the total closure of the country around the early 1640s: Japanese potters had managed to replace the Jesuit-related yellow materi- als with the iron yellow, but could not replace the smalt needed for overglaze blue decoration as it wasn’t avail- able in China at the time. Therefore they had to rely entirely on imports by the Dutch, the only Europeans allowed to trade with Japan during the Tokugawa Shogu- nate. Trade of ceramic materials and development of pro- duction techniques became the major factors impacting the competition between potters. The profitable market for enameled wares became the aim of Arita kilns as well as their fierce battleground. To conclude this part, the results demonstrate that in the late Meiji period (1868–1912), as soon as European presence became relevant once again in the country, con- trary to the Edo period, Japanese potters finally managed, for the first time, to establish their own production of antimony yellow and synthetic blue materials. The main difference between the closed country policy of the Edo period and the Meiji policy of strong westernization is Fig. 10 Naka Shirakawa shard [4], a Schematic of XRF signal of chemical elements recorded on overglaze blue-green, b detail of analysed overglaze blue-green decoration Page 15 of 17Montanari et al. Herit Sci (2020) 8:48 that the latter led to the establishment of a full-fledged, state-of-the-art industry that enabled Japan to become, once again after 400 years, the hub for European materi- als and technology in the Far East. Ready‑to‑use pigments in the twentieth century: from Europe to Japan and China The scientific evidences also confirm the suggestions by Kerr, Wood and Watt [7, 43, 71] regarding the replace- ment of Jingdezhen overglaze and underglaze materi- als with newly developed and ready-to-use pigments imported from France, Germany and Japan in the early twentieth century. In particular, Watt reports the practice at Jingdezhen of mixing natural low-grade Chinese cobalt ores with newly developed synthetic blue pigments in the early twentieth century [71]. The technology trans- fer appears very clear on the basis of our results: shard #7 (Fig.  5a) reveals that such practice started in Arita in the late nineteenth century and then spread to Jingdez- hen, when the new Japanese-made pigments became an important part of the trade with China in the early twen- tieth century. Further confirmation comes from the Sb– Cu green enamel detected on shard #11 (Fig. 7b). Takamatsu also describes the preparation of blue enamels by listing the reagents involved in the process: he basically tells us that the imported ready-to-use mate- rial Hanakonjo was embedded into a Pb–Si–K matrix (a mixture of Shiratama, Tonotsuchi and Hinookaseki) [31]. This further confirms that the Japanese practice of using imported blue pigments from Europe for paintings and ceramics had not changed since the first encounter with the Jesuits in the late sisteenth century. The results pre- sented for shard #9 and a modern high artistic value cup further prove this continued practice (Fig. 6a, b). Shard #9 therefore offers a clear instance of the shift from the smalt-based recipe to the newly developed Co- based synthetic ones: the XRF spectrum shows a com- pound of Co and Zn (Fig.  7a). Such composition is in perfect agreement with the recipe published in 1869 by Thomas Salter in Field’s Chromatography or Treatise on Colours and Pigments as Used by Artists [66]. The author lists a Zinc-Cobalt Blue saying that “… For tinting porce- lain…it is admirably adapted, imparting thereto a very pure dark blue of extraordinary beauty”. Charles-Ernest Guignet further describes in La céramique ancienne et moderne (1899) the effects that the incorporation of Zn in the blue recipe allows to achieve: “… For sky blues, add zinc oxide…so that the mixture takes on a tone closer to pure blue”. Conclusions The analytic results reported here demonstrate how the study of ceramic enamels may provide valuable information not only on the history of porcelain pro- duction, but also on materials employed in Asian paint- ing and printing traditions. We have demonstrated how the long-thought exclusive Chinese influence on Japan, especially on ceramics and paintings, was only one aspect of the Japanese technological development of coloring agents. The arrival of Europeans in 1543 triggered a privileged exchange that enabled Japan to become the first hub of European technology in the Far East, thus reversing, for the first time, the centuries-old predominance of China as the main actor in the spread of western culture throughout Asia. The new evidence confirms that the pattern of influence established by the Jesuits in the late 16th century laid the foundation for a new and independent Japanese cultural develop- ment. Such development will strongly influence China in the late nineteenth and twentieth centuries. Exten- sive experimentation with new synthetic pigments and enamels imported from the Old Continent will mark this extraordinary process of Japanese innovation. However, the two traditions will be distinguished by the extensive use of smalt in Japan as opposed to its very limited use in Chinese paintings, as well as in Chinese ceramic production before the eighteenth century. The new evidences reveal that synthetic pigments started to be produced in Japan in the twentieth cen- tury on the basis of European original recipes. Such pigments will also be exported to China for porcelain decoration. Japan, as occurred four centuries earlier with the Jesuits, became once again the hub for western material circulation in the Far East. Moreover, Raman results have demonstrated, for the first time on Far-Eastern porcelains, that the shift of the Pb mode of the A2O’ lattice of lead antimonate yellow (Naples Yellow) provides important information on the firing temperature for enamel decoration. Such charac- teristic, along with its chemical composition, enables the identification of the area of origin and period of manufacture of the yellow enamel. Abbreviations EDXRF: Energy-dispersive X-ray fluorescence; XRF: X-ray fluorescence. Acknowledgements We would like to thank Mr. Yoshihisa Tsuruta. Authors’ contributions The research project was conceived by RM, who also prepared the manu- script. The shards were selected by NM and RM. The analyses were carried out by RM, MFA, SS. The results were interpreted by RM, MFA, PhC, and CP. PhC and CP also revised the manuscript. All authors read and approved the final manuscript. Page 16 of 17Montanari et al. Herit Sci (2020) 8:48 Funding Non applicable. Availability of data and materials All data is available upon request. Competing interests The authors declare that they have no competing interests. Author details 1 Independent Researcher, Expert Witness, Rome, Italy. 2 Arita Museum of His- tory, 1-4-1, Izumiyama, Arita-cho, Nishimatsuura-Gun, Saga, Japan. 3 Sorbonne Université, CNRS, MONARIS, 4 Place Jussieu, C49, 75005 Paris, France. 4 S.T.Art- Test, Via Stovigliai, 88, 93015 Niscemi, CL, Italy. 5 University of Tuscia, Labora- tory of Diagnostics and Materials Science, Largo dell’Università, 01100 Viterbo, Italy. 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European ceramic technology in the Far East: enamels and pigments in Japanese art from the 16th to the 20th century and their reverse influence on China Abstract Introduction and historical context Materials and methods Analyzed shards XRF spectrometer: experimental and measurement parameters Raman spectroscopy Results and discussion Overglaze yellow enamels Raman analysis XRF analysis Blue coloring agent and overglaze enamels Overglaze green enamels Naples yellow pigment: a tracer of Europe-Japan technological exchanges Preparation procedures The Raman signature of the pyrochlore solid solution Historical recipes and scientific evidence: the connections Provenance and use of antimony European materials for painting and ceramics Porcelain and paintings: one coloring agent for both productions Persecutions and closure of the country Blue coloring agents Smalt: provenance and use Foreign coloring agents in the late Edo period (eighteenth and nineteenth centuries) Comparison with China: smalt and European chromophores European recipes for the global market: production innovations in the porcelain industry of Arita Ready-to-use pigments in the twentieth century: from Europe to Japan and China Conclusions Acknowledgements References