A Micro‐raman and Internal Microstratigraphic Study of Ceramic Sherds From the Kilns of the Medici Castle at Cafaggiolo*

Santis, A. De; Mattei, Elisabetta; Montini, I.; Pelosi, Claudia

doi:10.1111/j.1475-4754.2011.00604.x

Cited by 6 publications

(6 citation statements)

References 46 publications

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“…How to cite this article: P. Colomban, M. Gironda, H. G. M. Edwards, V. Mesqui, J Raman Spectrosc 2021, 52 (12), 2246. https://doi. org/10.1002/jrs.6111…”

Section: Supporting Informationmentioning

confidence: 99%

The enamels of the first (soft‐paste) European blue‐and‐white porcelains: Rouen, Saint‐Cloud and Paris factories: Complementarity of Raman and X‐ray fluorescence analyses with mobile instruments to identify the cobalt ore

Colomban

Gironda²,

Edwards

et al. 2021

J Raman Spectroscopy

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The first porcelains made in Europe during the 17th century and the very beginning of the 18th century, that is, before the discovery of kaolin in Saxony (Germany), are rare and technical analyses very limited. In contrast with Meissen Böttger porcelain based on kaolin, these porcelains are made with sand and chymie, like Ottoman fritware. A selection of the blue‐and‐white artefacts belonging to the French national collection is analysed on‐site with mobile portable X‐ray fluorescence (pXRF) and Raman set‐ups: two were assigned to the Poterat Factory at Rouen, three to the Saint‐Cloud Factory and two to the Pavie Factory (Paris). Three types of enamels are identified, lead‐rich (as expected) but also two different lead‐alkaline‐earth alkali enamels, one artefact being covered both with lead‐rich and lead‐poor enamel. The polymerization index deduced from the relative intensity of SiO4 bending and stretching bands indicates different temperatures of firing. Tin is detected in most of the enamels by X‐ray fluorescence (XRF), but cassiterite opacification is only observed for the Pavie Factory artefacts. Arsenic is detected in the blue areas due to the use of European cobalt ores. Comparison of trace and minor elements as well as the type of enamel used suggest that the pot assigned to the Rouen Factory fits much better with a production from the Saint‐Cloud Factory. The two porcelains assigned to the Pavie Factory exhibit similar XRF and Raman signatures that support the attribution based on visual criteria. Combination of the mobile noninvasive XRF and Raman instruments may allow the reliable classification of artefacts on‐site. Raman scattering is very efficient to detect (on‐site) As‐based minor phases.

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“…How to cite this article: P. Colomban, M. Gironda, H. G. M. Edwards, V. Mesqui, J Raman Spectrosc 2021, 52 (12), 2246. https://doi. org/10.1002/jrs.6111…”

Section: Supporting Informationmentioning

confidence: 99%

The enamels of the first (soft‐paste) European blue‐and‐white porcelains: Rouen, Saint‐Cloud and Paris factories: Complementarity of Raman and X‐ray fluorescence analyses with mobile instruments to identify the cobalt ore

Colomban

Gironda²,

Edwards

et al. 2021

J Raman Spectroscopy

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show abstract

“…Although scholarly attention has mainly focused on the masterpieces of painterly maiolica of the Italian Renaissance (Liverani 1957;Whitehouse 1967;Whitehouse 1978;Goldthwaite 1989;Fabbri et al 1990;Kingery 1993;Ruffini et al 2005;Viti et al 2003;Tite 1991Tite , 2008Antonelli et al 2014), a multifaceted stylistic and technological world is emerging on the Italian ceramic production of that period (Gardini and Mannoni 1995;Clark et al 1997;Capelli et al 2002;Comodi et al 2004;Laganara Fabiano 2004;Ricci et al 2005;Capelli and Cabella 2010;De Santis et al 2012;Heimann et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Glazed sgraffito ware from Torre Alemanna (Foggia, fifteenth to sixteenth century A.D.): technological aspects of a local production

Fioretti

Eramo

Monno

et al. 2022

Archaeol Anthropol Sci

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The archaeometric investigation of 46 potsherds of “Torre Alemanna type” pottery aimed to define a compositional reference group and to understand the technological characteristics of its production. Principal component analysis applied to bulk chemical data (XRF) of the ceramic body showed a strong compositional homogeneity. Their comparison with local clays and 6 fragments of bricks sampled from the ceramic kiln, on the one hand, revealed the use of alluvial clays as raw material and, on the other hand, proved their fractionation for the production of pottery. The mineralogical assemblages detected by X-ray powder diffraction analysis inferred maximum firing temperatures between 750 and 1000 °C for the ceramic body. Polarising optical microscopy and scanning electron microscopy with energy dispersive spectroscopy (SEM–EDS) investigations on coating revealed the presence of quartz-rich white engobe covered with a high lead transparent glaze. The polychromatic decoration was analysed by colorimetry and EDS to compare the colour characteristics through all the potsherds. A temperature range between 780 and 950 °C of liquidus temperatures was inferred from the ternary phase diagram of PbO-Al2O3-SiO2 system. Overlap of temperature ranges for sintering of the ceramic body and maturing glaze points to a single firing of the Torre Alemanna type ware. The results obtained define the reference compositional group and technology of the Torre Alemanna type ware, already attested in several archaeological contexts of southern Italy, and showed a technological continuity with the past about the use of local carbonate-rich clays to produce fine pottery.

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“…Ceramic artefacts are investigated using a variety of analytical techniques. [1][2][3][4][5][6] Usually, non-destructive techniques are preferred in order to preserve the artefact's integrity, but in cases where provenance is of concern, semi-destructive techniques such as X-ray fluorescence (XRF), X-ray diffraction (XRD), and petrography are utilised. For example, when performing quantitative elemental analysis of ceramic sherds, XRF analysis is performed on powder samples made by crushing and then milling pieces of the sherds in question, into fine homogenous powders, [7] pressed into pellets [8] or fused into glass beads.…”

Section: Introductionmentioning

confidence: 99%

“…Ceramic artefacts are investigated using a variety of analytical techniques . Usually, non‐destructive techniques are preferred in order to preserve the artefact's integrity, but in cases where provenance is of concern, semi‐destructive techniques such as X‐ray fluorescence (XRF), X‐ray diffraction (XRD), and petrography are utilised.…”

Section: Introductionmentioning

confidence: 99%

Identification of mineral inclusions in archaeological ceramics using microbeam X‐ray fluorescence spectrometry

Attaelmanan

2014

X-Ray Spectrometry

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Archaeological ceramics are subjected to chemical and geochemical analyses in order to ascertain production techniques and provenance. Many analytical techniques are currently available for the determination of qualitative and quantitative characteristics pertaining to clay composition and structure. Microbeam XRF is utilised in this report to analyse mineral inclusions present in Mleiha ceramics in order to establish better provenance data. A total of 67 mineral inclusions of different sizes and colours were analysed. The majority of the sampled inclusions (94%) were silicates, and only 6% were calcites. A total of 35 inclusions from the former group were olivine minerals composed of a mixture of Mg, Si, and Fe oxides constituting 87-99% of the inclusions' mass, in addition to 13 inclusions composed mainly of Al, Si, and Ca oxides with sum concentrations ranging from 80% to 98%. Figure 6. (a) Various coloured mineral inclusions. M2-14, M2-15, M2-16, and M2-17. (b) Two different mineral inclusions. Calcite M3-01 and M3-02 and silicate M3-03 and M3-04.

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A Micro‐raman and Internal Microstratigraphic Study of Ceramic Sherds From the Kilns of the Medici Castle at Cafaggiolo*

Cited by 6 publications

References 46 publications

The enamels of the first (soft‐paste) European blue‐and‐white porcelains: Rouen, Saint‐Cloud and Paris factories: Complementarity of Raman and X‐ray fluorescence analyses with mobile instruments to identify the cobalt ore

The enamels of the first (soft‐paste) European blue‐and‐white porcelains: Rouen, Saint‐Cloud and Paris factories: Complementarity of Raman and X‐ray fluorescence analyses with mobile instruments to identify the cobalt ore

Glazed sgraffito ware from Torre Alemanna (Foggia, fifteenth to sixteenth century A.D.): technological aspects of a local production

Identification of mineral inclusions in archaeological ceramics using microbeam X‐ray fluorescence spectrometry

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