Yellow pigments based on lead, tin, and antimony: Ancient recipes, synthesis, characterization, and hue choice in artworks

Agresti, Giorgia; Baraldi, Pietro; Pelosi, Claudia; Santamaria, Ulderico

doi:10.1002/col.22026

Cited by 25 publications

(20 citation statements)

References 19 publications

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“…On the other hand, the APB3 sample, fired at a temperature of 1050 • C, has completely different characteristics in respect to APB1 and APB2, both in terms of particle and colour parameters. Specifically, the colour data of APB1, APB2, and APB3 samples show how APB1 and APB2 have similar colour features if compared to APB3; moreover, the first two yellows exhibit particle heterogeneity in respect to APB3, confirming the results obtained by previous findings on chemical composition [16]. In fact, APB1 and APB2 are characterised by a compositional heterogeneity, while APB3 is a homogeneous dark yellow powder with a reddish hue, as shown by the significantly higher value of the a* coordinate.…”

Section: Comparison Of Colour and Particle Analysissupporting

confidence: 88%

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

et al. 2021

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This paper reports the results of particle size analysis and colour measurements concerning yellow powders, synthesised in our laboratories according to ancient recipes aiming at producing pigments for paintings, ceramics, and glasses. These pigments are based on lead and antimony as chemical elements, that, combined in different proportions and fired at different temperatures, times, and with various additives, gave materials of yellow colours, changing in hues and particle size. Artificial yellow pigments, based on lead and antimony, have been widely studied, but no specific investigation on particle size distribution and its correlation to colour hue has been performed before. In order to evaluate the particle size distribution, segmentation of sample data has been performed using the MATLAB software environment. The extracted parameters were examined by principal component analysis (PCA) in order to detect differences and analogies between samples on the base of those parameters. Principal component analysis was also applied to colour data acquired by a reflectance spectrophotometer in the visible range according to the CIELAB colour space. Within the two examined groups, i.e., yellows containing NaCl and those containing K-tartrate, differences have been found between samples and also between different areas of the same powder indicating the inhomogeneity of the synthesised pigments. On the other hand, colour data showed homogeneity within each yellow sample and clear differences between the different powders. The comparison of results demonstrates the potentiality of the particle segmentation and analysis in the study of morphology and distribution of pigment powders produced artificially, allowing the characterisation of the lead and antimony-based pigments through micro-image analysis and colour measurements combined with a multivariate approach.

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Section: Comparison Of Colour and Particle Analysissupporting

confidence: 88%

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

et al. 2021

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“…Solid-state synthesis. Temperatures between 923 K and 1173 K have been used for the synthesis of Pb 2 SnO 4 powder by solid-state reaction (Gavarri et al, 1981;Hashemi et al, 1992;Clark et al, 1995;Chen et al, 2000;Hradil et al, 2007;Pelosi et al, 2010;Denisov et al, 2012;Agresti et al, 2016). For our experiments we chose a synthesis temperature of 1123 (1) K, in order to avoid the presence of PbSnO 3 which decomposes above 1073 K and to prevent decomposition of Pb 2 SnO 4 which is expected to occur above 1173 K (Xing et al, 2004).…”

Section: Methodsmentioning

confidence: 99%

Pressure-induced Pb–Pb bonding and phase transition in Pb₂SnO₄

Spahr¹,

Stękiel²,

Zimmer³

et al. 2020

Acta Crystallogr Sect B

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High-pressure single-crystal to 20 GPa and powder diffraction measurements to 50 GPa, show that the structure of Pb2SnO4 strongly distorts on compression with an elongation of one axis. A structural phase transition occurs between 10 GPa and 12 GPa, with a change of space group from Pbam to Pnam. The resistivity decreases by more than six orders of magnitude when pressure is increased from ambient conditions to 50 GPa. This insulator-to-semiconductor transition is accompanied by a reversible appearance change from transparent to opaque. Density functional theory-based calculations show that at ambient conditions the channels in the structure host the stereochemically-active Pb 6s 2 lone electron pairs. On compression the lone electron pairs form bonds between Pb2+ ions. Also provided is an assignment of irreducible representations to the experimentally observed Raman bands.

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“…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][14][15][16], Limoges metal wares [17], and for preparing painting pigments [18,19]. Both end-members of pyrochlore solid solutions (lead-tin yellow and lead antimonate yellow) as well as more complex solid solutions had been largely used since Roman times [20][21][22].…”

Section: Introduction and Historical Contextmentioning

confidence: 99%

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

Montanari

Murakami²,

Colomban

et al. 2020

Herit Sci

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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 Japanese 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.

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Yellow pigments based on lead, tin, and antimony: Ancient recipes, synthesis, characterization, and hue choice in artworks

Cited by 25 publications

References 19 publications

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

Pressure-induced Pb–Pb bonding and phase transition in Pb₂SnO₄

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

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Yellow pigments based on lead, tin, and antimony: Ancient recipes, synthesis, characterization, and hue choice in artworks

Cited by 25 publications

References 19 publications

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

Yellow Pigment Powders Based on Lead and Antimony: Particle Size and Colour Hue

Pressure-induced Pb–Pb bonding and phase transition in Pb2SnO4

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

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Pressure-induced Pb–Pb bonding and phase transition in Pb₂SnO₄