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Egyptian blue

February 15, 2024

"Caeruleum" redirects here. For the genus of lamprey, see Caeruleum (lamprey). For the genus of lichen fungus, see Caeruleum (lichen).

Egyptian blue, also known as calcium copper silicate (CaCuSi4O10 or CaOCuO(SiO2)4 (calcium copper tetrasilicate)) or cuprorivaite,[1] is a pigment that was used in ancient Egypt for thousands of years. It is considered to be the first synthetic pigment.[2] It was known to the Romans by the name caeruleum. After the Roman era, Egyptian blue fell from use and, thereafter, the manner of its creation was forgotten. In modern times, scientists have been able to analyze its chemistry and reconstruct how to make it.

Egyptian blue
 
    Color coordinates
Hex triplet#1034A6
sRGBB (r, g, b)(16, 52, 166)
HSV (h, s, v)(226°, 90%, 65%)
CIELChuv (L, C, h)(28, 82, 263°)
Source[Unsourced]
ISCC–NBS descriptorVivid blue
B: Normalized to [0–255] (byte)

The ancient Egyptian word wꜣḏ signifies blue, blue-green, and green.

The first recorded use of "Egyptian blue" as a color name in English was in 1809.[3]

Definition edit

 
Pyxis made out of "Egyptian blue" faience: Imported to Italy from northern Syria, it was produced 750–700 BC. (Shown at Altes Museum in Berlin)

Egyptian blue is a synthetic blue pigment produced from a mixture of silica, lime, copper, and an alkali. Its color is due to a calcium-copper tetrasilicate CaCuSi4O10 of the same composition as the naturally occurring mineral cuprorivaite.[2] It was first synthesized in Egypt during the Fourth Dynasty and used extensively until the end of the Roman period in Europe,[2] after which its use declined significantly.[4]

The term for it in the Egyptian language is ḫsbḏ-ỉrjt (khesbedj irtiu), which referred to artificial lapis lazuli (ḫsbḏ).[5] It was used in antiquity as a blue pigment to color a variety of different media such as stone, wood, plaster, papyrus, and canvas, and in the production of numerous objects, including cylinder seals, beads, scarabs, inlays, pots, and statuettes. Sometimes, it is referred to in Egyptological literature as blue frit. Some have argued that this is an erroneous term that should be reserved for use to describe the initial phase of glass or glaze production,[6] while others argue that Egyptian blue is a frit in both the fine and coarse form since it is a product of solid state reaction.[7] Its characteristic blue color, resulting from one of its main components—copper—ranges from a light to a dark hue, depending on differential processing and composition.

Apart from Egypt, it has also been found in the Near East, the Eastern Mediterranean, and the limits of the Roman Empire. It is unclear whether the pigment's existence elsewhere was a result of parallel invention or evidence of the technology's spread from Egypt to those areas.

History and background edit

The ancient Egyptians held the color blue in very high regard and were eager to present it on many media and in a variety of forms. They also desired to imitate the semiprecious stones turquoise and lapis lazuli, which were valued for their rarity and stark blue color. Use of naturally occurring minerals such as azurite to acquire this blue was impractical, as these minerals were rare and difficult to work.[citation needed] Therefore, to have access to the large quantities of blue color to meet demand, the Egyptians needed to manufacture the pigment themselves.

The earliest evidence for the use of Egyptian blue, identified by Egyptologist Lorelei H. Corcoran of The University of Memphis, is on an alabaster bowl dated to the late pre-dynastic period or Naqada III (circa 3250 BC), excavated at Hierakonpolis, and now in the Museum of Fine Arts, Boston.[8] In the Middle Kingdom (2050–1652 BC) it continued to be used as a pigment in the decoration of tombs, wall paintings, furnishings, and statues, and by the New Kingdom (1570–1070 BC) began to be more widely used in the production of numerous objects. Its use continued throughout the Late period and Greco-Roman period, only dying out in the fourth century AD, when the secret to its manufacture was lost.[9]

No written information exists in ancient Egyptian texts about the manufacture of Egyptian blue in antiquity, and it was first mentioned only in Roman literature by Vitruvius during the first century BC.[10] He refers to it as caeruleum and describes in his work De architectura how it was produced by grinding sand, copper, and natron, and heating the mixture, shaped into small balls, in a furnace. Lime is necessary for the production as well, but probably lime-rich sand was used. Theophrastus gives it the Greek term κύανος (kyanos, blue),[11] which originally probably referred to lapis lazuli. Finally, only at the beginning of the nineteenth century was interest renewed in learning more about its manufacture when it was investigated by Humphry Davy in 1815,[12] and others such as W. T. Russell and F. Fouqué.

Composition and manufacture edit

Several experiments have been carried out by scientists and archaeologists interested in analyzing the composition of Egyptian blue and the techniques used to manufacture it. It is now generally regarded as a multiphase material that was produced by heating together quartz sand, a copper compound, calcium carbonate, and a small amount of an alkali (ash from salt-tolerant, halophyte plants or natron) at temperatures ranging between 800 and 1,000 °C (1,470 and 1,830 °F) (depending on the amount of alkali used) for several hours.[13] The result is cuprorivaite or Egyptian blue, carbon dioxide, and water vapor:

Cu2CO3(OH)2 + 8 SiO2 + 2 CaCO3 → 2 CaCuSi4O10 + 3 CO2 + H2O

In its final state, Egyptian blue consists of rectangular blue crystals together with unreacted quartz and some glass. From the analysis of a number of samples from Egypt and elsewhere, the weight percentage of the materials used to obtain Egyptian blue in antiquity was determined usually to range within these amounts:[13]

To obtain theoretical cuprorivaite, where only blue crystals occur, with no excess of unreacted quartz or formation of glass, these percentages would need to be used:[13]

  • 64% silica
  • 15% calcium oxide
  • 21% copper oxide

However, none of the analyzed samples from antiquity was made of this definitive composition, as all had excesses of silica, together with an excess of either CuO or CaO.[14] This may have been intentional; an increase in the alkali content results in the pigment containing more unreacted quartz embedded in a glass matrix, which in turn results in a harder texture.[13] Lowering the alkali content (less than 1%), though, does not allow glass to form and the resultant Egyptian blue is softer, with a hardness of 1–2 Mohs.[14]

In addition to the way the different compositions influenced texture, the way Egyptian blue was processed also had an effect on its texture, in terms of coarseness and fineness. Following a number of experiments, Tite et al. concluded that for fine-textured Egyptian blue, two stages were necessary to obtain uniformly interspersed crystals. First, the ingredients are heated, and the result is a coarse-textured product. This is then ground to a fine powder and water is added. The paste is then reshaped and fired again at temperatures ranging between 850 and 950 °C for one hour. These two stages possibly were needed to produce a paste that was fine enough for the production of small objects. Coarse-textured Egyptian blue, though, would not have gone through the second stage. Since it usually is found in the form of slabs (in the dynastic periods) and balls (in the Greco-Roman period), these either could have been awaiting to be processed through a second stage, where they would be ground and finely textured, or they would have been ground for use as a blue pigment.[13]

The shade of blue reached was also related to the coarseness and fineness of Egyptian blue as it was determined by the degree of aggregation of the Egyptian blue crystals. Coarse Egyptian blue was relatively thick in form, due to the large clusters of crystals which adhere to the unreacted quartz. This clustering results in a dark blue color that is the appearance of coarse Egyptian blue. Alternatively, fine-textured Egyptian blue consists of smaller clusters that are uniformly interspersed between the unreacted quartz grains and tends to be light blue in color.[13] Diluted light blue, though, is used to describe the color of fine-textured Egyptian blue that has a large amount of glass formed in its composition, which masks the blue color, and gives it a diluted appearance. It depends on the level of alkali added to the mixture, so with more alkali, more glass formed, and the more diluted the appearance.[13] This type of Egyptian blue is especially evident during the eighteenth dynasty and later, and probably is associated with the surge in glass technology at this time.[6]

If certain conditions were not met, the Egyptian blue would not be satisfactorily produced. For example, if the temperatures were above 1050 °C, it would become unstable.[15] If too much lime was added, wollastonite (CaSiO3) forms and gives the pigment a green color. Too much of the copper ingredients results in excesses of copper oxides cuprite and tenorite.[15]

Sources edit

The main component of Egyptian blue was the silica, and quartz sand found adjacent to the sites where Egyptian blue was being manufactured may have been its source,[13] although no concrete evidence supports this hypothesis. The only evidence cited is by Jakcsh et al., who found crystals of titanomagnetite, a mineral found in desert sand, in samples collected from the tomb of Sabni (sixth dynasty). Its presence in Egyptian blue indicates that quartz sand, rather than flint or chert, was used as the silica source. This contrasts with the source of silica used for glass-making at Qantir (New Kingdom Ramesside site), which is quartz pebbles and not sand.[16]

It is believed that calcium oxide was not added intentionally on its own during the manufacture of Egyptian blue, but introduced as an impurity in the quartz sand and alkali.[13] As to whether the craftsmen involved in the manufacture realized the importance of adding lime to the Egyptian blue mixture is not clear from this.

The source of copper could have been either a copper ore (such as malachite), filings from copper ingots, or bronze scrap and other alloys. Before the New Kingdom, evidence is scarce as to which copper source was being used, but it is believed to have been copper ores. During the New Kingdom, evidence has been found for the use of copper alloys, such as bronze, due to the presence of varying amounts of tin, arsenic, or lead found in the Egyptian blue material.[15] The presence of tin oxide could have come from copper ores that contained tin oxide and not from the use of bronze. However, no copper ores have been found with these amounts of tin oxide.[15] Why a switch from the use of copper ores in earlier periods, to the use of bronze scrap during the Late Bronze Age is unclear as yet.

The total alkali content in analyzed samples of Egyptian blue is greater than 1%, suggesting the alkali was introduced deliberately into the mixture and not as an impurity from other components. Sources of alkali either could have been natron from areas such as Wadi Natroun and El-Kab, or plant ash. By measuring the amounts of potash and magnesia in the samples of Egyptian blue, it is generally possible to identify which source of alkali had been used, since the plant ash contains higher amounts of potash and magnesia than the natron. However, due to the low concentration of alkali in Egyptian blue, which is a mere 4% or less, compared to glass, for example, which is at 10–20%, identifying the source is not always easy. The alkali source likely was natron,[14] although the reasons for this assumption are unclear. However, analysis by Jaksch et al. of various samples of Egyptian blue identified variable amounts of phosphorus (up to 2 wt %), suggesting the alkali source used was in actuality plant ash and not natron.[15] Since the glass industry during the Late Bronze Age used plant ash as its source of alkali,[17] a link in terms of the alkali used for Egyptian blue before and after the introduction of the glass industry might have been possible.

Archaeological evidence edit

Amarna edit

In the excavations at Amarna, Lisht, and Malkata at the beginning of the twentieth century, Petrie uncovered two types of vessels that he suggested were used in antiquity to make Egyptian blue: bowl-shaped pans and cylindrical vessels or saggers. In recent excavations at Amarna by Barry Kemp (1989), very small numbers of these "fritting" pans were uncovered, although various remaining pieces of Egyptian blue 'cake' were found, which allowed the identification of five different categories of Egyptian blue forms and the vessels associated with them: large round flat cakes, large flat rectangular cakes, bowl-shaped cakes, small sack-shaped pieces, and spherical shapes.[18] No tin was found in the samples analyzed, which the authors suggest is an indication that use of scrap copper was possible instead of bronze.[19]

Qantir edit

In the 1930s, Mahmud Hamza excavated a number of objects related to the production of Egyptian blue at Qantir, such as Egyptian blue cakes and fragments in various stages of production,[20] providing evidence that Egyptian blue was actually produced at the site. Recent excavations at the same site uncovered a large copper-based industry, with several associated crafts, namely bronze-casting, red-glass making, faience production, and Egyptian blue.[20] Ceramic crucibles with adhering remains of Egyptian blue were found in the excavations, suggesting again it had been manufactured on site. These Egyptian blue 'cakes' possibly were later exported to other areas around the country to be worked, as a scarcity of finished Egyptian blue products existed on site. For example, Egyptian blue cakes were found at Zawiyet Umm el-Rakham, a Ramesside fort near the Libyan coast, indicating in fact that the cakes were traded, and worked at and reshaped away from their primary production site.[20]

Connections with other vitreous material and with metals edit

 
Blue faience saucer and stand, New Kingdom (1400–1325 BC)

Egyptian blue is closely related to the other vitreous materials produced by the ancient Egyptians, namely glass and Egyptian faience, and it is possible that the Egyptians did not employ separate terms to distinguish the three products from one another.[9] Although it is easier to distinguish between faience and Egyptian blue, due to the distinct core of faience objects and their separate glaze layers, it sometimes is difficult to differentiate glass from Egyptian blue due to the very fine texture that Egyptian blue occasionally could have. This is especially true during the New Kingdom, as Egyptian blue became more refined and glassy and continued as such into the Greco-Roman period.[21]

Since Egyptian blue, like faience, is a much older technology than glass, which only begins during the reign of Thutmose III (1479–1425 BC), changes in the manufacture of Egyptian blue undoubtedly were associated with the introduction of the glass industry.

Analysis of the source of copper used in the manufacture of Egyptian blue indicates a relationship with the contemporaneous metal industry. Whereas in the earlier periods, it is most probable that copper ores were used, during the reign of Tutmosis III, the copper ore is replaced by the use of bronze filings.[6] This has been established by the detection of a specific amount of tin oxide in Egyptian blue, which only could have resulted from the use of tin bronze scraps as the source of copper, which coincides with the time when bronze became widely available in ancient Egypt.

Occurrences outside Egypt edit

Egyptian blue was found in Western Asia during the middle of third millennium BC in the form of small artifacts and inlays, but not as a pigment.[6] It was found in the Mediterranean area at the end of the Middle Bronze Age, and traces of tin were found in its composition suggesting the use of bronze scrap instead of copper ore as the source of copper.[6] During the Roman period, use of Egyptian blue was extensive, as a pot containing the unused pigment, found in 1814 in Pompeii, illustrates. It was also found as unused pigment in the tombs of a number of painters. Etruscans also used it in their wall paintings. The related Chinese blue has been suggested as having Egyptian roots.

Later, Raphael used Egyptian blue in his Triumph of Galatea.[22]

Roman production of Egyptian blue edit

 
Raman microspectroscopic phase distribution map of a paint layer from the church of St. Peter above Gratsch showing several minor, major and trace compounds of Egyptian blue.[23]

Around the turn of the eras, Roman sources report that a certain Vestorius transferred the production technology from Alexandria to Pozzuoli near Naples (Campania, Southern Italy).[24] In fact, archaeological evidences confirm production sites in the northern Phlegraean Fields and seem to indicate a monopoly in the manufacture and trade of pigment spheres. Due to its almost exclusive use, Egyptian blue is the blue pigment par excellence of Roman antiquity; its art technological traces vanish in the course of the Middle Ages.[23]

In 2021, Early Medieval Egyptian blue (fifth/sixth century AD) was identified on a monochrome blue mural fragment from the church of St. Peter above Gratsch (South Tyrol, Northern Italy). By a new analytical approach based on Raman microspectroscopy, 28 different minerals with contents from the percent range down to 100 ppm were identified. Inclusion of knowledge from neighbouring disciplines made possible to read out the information about the type and provenance of the raw materials, synthesis and application of the pigment and ageing of the paint layer preserved in the previously not accessible trace components, and thus to reconstruct the individual "biography" of the Egyptian blue from St. Peter. This paradigm shift in the research history of Egyptian blue provided natural scientific evidences for the production in the northern Phlegraean fields (agreement with trace minerals found in the beach sands at the Gulf of Gaeta), the use of a sulphidic copper ore (instead of often-mentioned metallic copper or bronze), and plant ash as flux in the raw material mixture. Furthermore, indications for a synthesis predominated by solid state reactions were found, while the melting of the raw materials into glass most likely played a negligible role.[23]

A follow-up study on Roman Imperial pigment balls excavated in Aventicum and Augusta Raurica (Switzerland; first to third century AD) confirmed the results in 2022. The consistent composition of around 40 identified minerals establishes a connection to the northern Phlegraean Fields; a sulphidic copper ore and plant ash have also left their marks. Thus, the Roman production monopoly probably existed for centuries. In addition, the analyses revealed unwanted by-products of the synthesis, locally limited to microparticles on the sphere's surfaces, which can be traced back to suboptimal burning times or mixing ratios, respectively: a cuprorivaite with crystal defects in its layer structure and a copper-bearing green glass phase, characterised by Raman spectroscopy for the first time.[25]

Modern applications edit

Egyptian blue's extremely powerful and long-lived infrared luminescence under visible light has enabled its presence to be detected on objects which appear unpainted to the human eye.[26] This property has also been used to identify traces of the pigment on paintings produced as late as the sixteenth century, long after its use was presumed to have died out.[27] The luminescence in the near-infrared, where neither fat nor hemoglobin show high absorption coefficients, in conjunction with the capacity of Egyptian blue to delaminate by splitting into nanosheets after immersion in water, also indicates it may have several high-technology applications, such as in biomedicine (e.g. bioimaging), telecommunications, laser technology, and security inks.[28][29][30]

Researchers at the Lawrence Berkeley National Laboratory discovered that Egyptian blue pigment absorbs visible light, and emits light in the near-infrared range. This suggests that Egyptian blue pigment could be used in construction materials designed to cool rooftops and walls in sunny climates, and for tinting glass to improve photovoltaic cell performance.[31][32][33]

See also edit

References edit

  1. ^ Cuprorivaite, mindat.org
  2. ^ a b c Eastaugh, Nicholas; Walsh, Valentine; Chaplin, Tracey; Siddall, Ruth (2004). "Egyptian blue". The pigment compendium: Optical microscopy of historical pigments. Oxford, UK: Elsevier Butterworth Heinemann. pp. 147–148.
  3. ^ Maerz and Paul A Dictionary of Color New York:1930 McGraw-Hill Page 194; Color Sample of Sunset: Page 93 Plate 35 Color Sample L8
  4. ^ McCouat, Philip (2018). . artinsociety.com. Journal of Art in Society. Archived from the original on 2019-03-28. Retrieved 2019-05-29.
  5. ^ Pagès-Camagna, S. (1998). "Bleu et vert égyptiens en question: vocabulaire et analyses". In Colinart S, Menu M, eds., La couleur dans la peinture et l'émaillage de l'Egypte Ancienne, CUEBC, Ravello, 20–22 March 1997, Edipuglia, Bari, pp. 51–59.
  6. ^ a b c d e Lee, L.; Quirke, S. (2000). "Painting materials". In P. Nicholson; I. Shaw (eds.). Ancient Egyptian materials and technology. Cambridge University Press. ISBN 978-0-521-45257-1.
  7. ^ Nicholson, P. T. & Henderson, J. (2000). "Glass". In: P. Nicholson and I. Shaw (eds.), Ancient Egyptian materials and technology. Cambridge: Cambridge University Press. ISBN 0-521-45257-0
  8. ^ Lorelei H. Corcoran, "The Color Blue as an 'Animator' in Ancient Egyptian Art", in Rachael B.Goldman, (ed.), Essays in Global Color History: Interpreting the Ancient Spectrum (New Jersey: Gorgias Press, 2016), pp. 59–82.
  9. ^ a b Chase, W. T. (1971:. "Egyptian blue as a pigment and ceramic material". In: R. Brill (ed.) Science and Archaeology. Cambridge, MMassachusetts: MIT Press. ISBN 0-262-02061-0
  10. ^ Vitruvius, De Architectura, Book VII, Chapter 11.
  11. ^ Theophrastus, De Lapidibus (On Stones), section 55.
  12. ^ Sir Humphry Davy (1815), "Some experiments and observations on the colours used in painting by the ancients", Philosophical Transactions of the Royal Society of London, vol. 105, pages 97–124. Reprinted in: The Collected Works of Sir Humphry Davy, ... (London, England: Smith, Elder, and Co., 1840), vol. VI, pp. 131–159.
  13. ^ a b c d e f g h i Tite, M.S., Bimson, M. & Cowell, M.R. (1987). "The technology of Egyptian blue". In M. Bimson; I.C. Freestone (eds.). Early Vitreous materials. British Museum occasional paper 56. London: British Museum. ISBN 978-0-86159-056-8.{{cite book}}: CS1 maint: multiple names: authors list (link)
  14. ^ a b c Tite, M.S., Bimson, M. & Cowell, M.R. (1984). "Technological examination of Egyptian blue". In J. B. Lambert (ed.). Archaeological Chemistry III. Advances in chemistry series 205. Washington, DC: American Chemical Society. ISBN 978-0-8412-0767-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  15. ^ a b c d e Jaksch, H., Seipel, W., Weiner, K.L. & El Goresy, A. (1983). "Egyptian Blue- Cuprorivaite, a window to Ancient Egyptian technology". Die Naturwissenschaften. 70 (11): 525–535. Bibcode:1983NW.....70..525J. doi:10.1007/BF00376668. S2CID 2457936.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  16. ^ Rehren, Th.; Pusch, E.B. (2005). "Late Bronze Age glass production at Qantir-Piramesses, Egypt". Science. 308 (5729): 1756–1758. Bibcode:2005Sci...308.1756R. doi:10.1126/science.1110466. PMID 15961663. S2CID 26214625.
  17. ^ Rehren, Th. (2001). "Aspects of the production of cobalt-blue glass in Egypt". Archaeometry. 43 (4): 483–489. doi:10.1111/1475-4754.00031.
  18. ^ Kemp, B. 1989, Amarna Reports V. London: Egypt Exploration Society. ISBN 0-85698-109-5
  19. ^ Weatherhead, F. & Buckley, A. 1989, Artists’ pigments from Amarna. In: B. Kemp (ed.), Amarna Reports V: 202–239. London: Egypt Exploration Society. ISBN 0-85698-109-5
  20. ^ a b c Rehren, Th.; Pusch, E. B.; Herold, A. (2001). "Problems and possibilities in workshop reconstruction: Qantir and the organization of LBA glass working sites". In A. J. Shortland (ed.). The social context of technological change, Egypt and the Near East 1650–1550 BC. Proceedings of a conference held at St Edmund Hall, Oxford 12–14 September 2000. Oxford: Oxbow Books. ISBN 978-1-84217-050-2.
  21. ^ Nicholson, P. T. & Peltenburg, E. (2000). "Egyptian faience". In: In: P. Nicholson and I. Shaw (eds.), Ancient Egyptian materials and technology. Cambridge: Cambridge University Press. ISBN 0-521-45257-0
  22. ^ "Ancient Hue Detected in Renaissance Painting - Archaeology Magazine". www.archaeology.org. Retrieved 2021-10-12.
  23. ^ a b c Petra Dariz; Thomas Schmid (2021). "Trace compounds in Early Medieval Egyptian blue carry information on provenance, manufacture, application, and ageing". Scientific Reports. 11 (11296): 11296. Bibcode:2021NatSR..1111296D. doi:10.1038/s41598-021-90759-6. ISSN 2045-2322. PMC 8163881. PMID 34050218.
  24. ^ ”The recipes for blue [sky blue] were first discovered in Alexandria, and subsequently Vestorius began to manufacture it in Puteoli as well.”, from: Vitruvius (Marcus Vitruvius Pollio): De architectura libri decem, Liber VII, Caput Xl (first century A.D.); English translation: Ingrid D. Rowland (1999). "Chapter 11: Blue". Ten Books on Architecture. Book 7: Finishing. Cambridge: Cambridge University Press. p. 94. ISBN 978-0-511-84095-1..
  25. ^ Petra Dariz; Thomas Schmid (2022). "Raman focal point on Roman Egyptian blue elucidates disordered cuprorivaite, green glass phase and trace compounds". Scientific Reports. 12 (15596): 15596. Bibcode:2022NatSR..1215596D. doi:10.1038/s41598-022-19923-w. ISSN 2045-2322. PMC 9481618. PMID 36114229.
  26. ^ Verri, G. (June 2009). "The spatially resolved characterisation of Egyptian blue, Han blue and Han purple by photo-induced luminescence digital imaging". Analytical and Bioanalytical Chemistry, Vol 394, Issue 4, pp. 1011–1021.
  27. ^ McCouat, P. "Egyptian blue: the colour of technology". Journal of Art in Society
  28. ^ Accorsi, G. et al. (2009). "The exceptional near-infrared luminescence of cuprorivaite (Egyptian blue)". Chemical Communications, Issue 23, p. 3392.
  29. ^ Bredal-Jørgensen, J. et al. (September 2011). "Striking presence of Egyptian blue identified in a painting by Giovanni Battista Benvenuto from 1524". Analytical and Bioanalytical Chemistry, Vol 401, Issue 4, p. 1433.
  30. ^ Gabriele Selvaggio, Alexey Chizhik, Robert Nißler, llyas Kuhlemann, Daniel Meyer, Loan Vuong, Helen Preiß, Niklas Herrmann, Florian A. Mann, Zhiyi Lv, Tabea A. Oswald, Alexander Spreinat, Luise Erpenbeck, Jörg Großhans, Volker Karius, Andreas Janshoff, Juan Pablo Giraldo, Sebastian Kruss: (2020). "Exfoliated near infrared fluorescent silicate nanosheets for (bio)photonics". In Nature Communications Vol. 11, No. 1495. doi:10.1038/s41467-020-15299-5
  31. ^ "Egyptian Blue for Energy Efficiency". Lawrence Berkeley Laboratory Heat Island Group. October 9, 2018. Retrieved 2018-10-14.
  32. ^ "World's 1st artificially-made pigment Egyptian blue, can help produce solar energy". India Today. October 11, 2018. Retrieved October 14, 2018.
  33. ^ "Scientists give solar PV a paint job". PV magazine USA. October 9, 2018. Retrieved October 14, 2018.

Further reading edit

  • Dayton, J. 1978, Minerals, Metals, Glazing & Man, or, Who Was Sesostris I? London: Harrap. ISBN 0-245-52807-5.
  • Lucas, A. & Harris. J.R. [1948] 1999, Ancient Egyptian Materials and Industries. Dover books on Egypt. Mineola, N.Y. : Dover. ISBN 0-486-40446-3.
  • Noll, W. 1981, Mineralogy and technology of the painted ceramics of ancient Egypt. In: M.J. Huges (ed.) Scientific studies in ancient ceramics. Occasional paper 19. London : British Museum, ISBN 0-86159-018-X.
  • Rehren, Th. & Pusch, E.B. & Herold, A. 1998, Glass coloring works within a copper-centered industrial complex in Late Bronze Age Egypt. In: McCray, P (ed), The prehistory and history of glassmaking technology. Ceramics and Civilization 8. Westerville, OH: American Ceramic Society. ISBN 1-57498-041-6
  • Riederer, J. 1997, Egyptian Blue. In: E.W. Fitzhugh, (ed.), Artists’ pigments 3: 23–45. Oxford university Press. ISBN 0-89468-256-3
  • Tite, M.S. 1985, Egyptian blue, faience and related materials: technological investigations. In: R.E. Jones & H.W. Catling (eds.) Science in Archaeology: Proceedings of a Meeting Held at the British School at Athens, January 1985. London : Leopard's Head. ISBN 0-904887-02-2.
  • Warner, T.E. 2011, Artificial Cuprorivaite CaCuSi4O10 (Egyptian Blue) by a Salt-Flux Method. In: Terence E. Warner, Synthesis, Properties and Mineralogy of Important Inorganic Materials, 26–49. Chichester: Wiley. ISBN 978-0-470-74611-0.
  • Wiedemann, H.G., Bayer, G. & Reller, A. 1998, Egyptian blue and Chinese blue. Production technologies and applications of two historically important blue pigments. In: S. Colinart & M. Menu (eds.), La couleur dans la peinture et lémaillage de l’Egypte Ancienne. Scienze e materiali del patrimonio culturale 4. Bari: Edipuglia. ISBN 88-7228-201-2.

External links edit

  • Egyptian blue, ColourLex
  • Egyptian Blue, Pigments through the ages

February 15, 2024
egyptian, blue, caeruleum, redirects, here, genus, lamprey, caeruleum, lamprey, genus, lichen, fungus, caeruleum, lichen, also, known, calcium, copper, silicate, cacusi4o10, caocuo, sio2, calcium, copper, tetrasilicate, cuprorivaite, pigment, that, used, ancie. Caeruleum redirects here For the genus of lamprey see Caeruleum lamprey For the genus of lichen fungus see Caeruleum lichen Egyptian blue also known as calcium copper silicate CaCuSi4O10 or CaOCuO SiO2 4 calcium copper tetrasilicate or cuprorivaite 1 is a pigment that was used in ancient Egypt for thousands of years It is considered to be the first synthetic pigment 2 It was known to the Romans by the name caeruleum After the Roman era Egyptian blue fell from use and thereafter the manner of its creation was forgotten In modern times scientists have been able to analyze its chemistry and reconstruct how to make it Egyptian blue Color coordinatesHex triplet 1034A6sRGBB r g b 16 52 166 HSV h s v 226 90 65 CIELChuv L C h 28 82 263 Source Unsourced ISCC NBS descriptorVivid blueB Normalized to 0 255 byte The ancient Egyptian word wꜣḏ signifies blue blue green and green The first recorded use of Egyptian blue as a color name in English was in 1809 3 Contents 1 Definition 2 History and background 3 Composition and manufacture 4 Sources 5 Archaeological evidence 5 1 Amarna 5 2 Qantir 6 Connections with other vitreous material and with metals 7 Occurrences outside Egypt 8 Roman production of Egyptian blue 9 Modern applications 10 See also 11 References 12 Further reading 13 External linksDefinition edit nbsp Pyxis made out of Egyptian blue faience Imported to Italy from northern Syria it was produced 750 700 BC Shown at Altes Museum in Berlin Egyptian blue is a synthetic blue pigment produced from a mixture of silica lime copper and an alkali Its color is due to a calcium copper tetrasilicate CaCuSi4O10 of the same composition as the naturally occurring mineral cuprorivaite 2 It was first synthesized in Egypt during the Fourth Dynasty and used extensively until the end of the Roman period in Europe 2 after which its use declined significantly 4 The term for it in the Egyptian language is ḫsbḏ ỉrjt khesbedj irtiu which referred to artificial lapis lazuli ḫsbḏ 5 It was used in antiquity as a blue pigment to color a variety of different media such as stone wood plaster papyrus and canvas and in the production of numerous objects including cylinder seals beads scarabs inlays pots and statuettes Sometimes it is referred to in Egyptological literature as blue frit Some have argued that this is an erroneous term that should be reserved for use to describe the initial phase of glass or glaze production 6 while others argue that Egyptian blue is a frit in both the fine and coarse form since it is a product of solid state reaction 7 Its characteristic blue color resulting from one of its main components copper ranges from a light to a dark hue depending on differential processing and composition Apart from Egypt it has also been found in the Near East the Eastern Mediterranean and the limits of the Roman Empire It is unclear whether the pigment s existence elsewhere was a result of parallel invention or evidence of the technology s spread from Egypt to those areas History and background editThe ancient Egyptians held the color blue in very high regard and were eager to present it on many media and in a variety of forms They also desired to imitate the semiprecious stones turquoise and lapis lazuli which were valued for their rarity and stark blue color Use of naturally occurring minerals such as azurite to acquire this blue was impractical as these minerals were rare and difficult to work citation needed Therefore to have access to the large quantities of blue color to meet demand the Egyptians needed to manufacture the pigment themselves The earliest evidence for the use of Egyptian blue identified by Egyptologist Lorelei H Corcoran of The University of Memphis is on an alabaster bowl dated to the late pre dynastic period or Naqada III circa 3250 BC excavated at Hierakonpolis and now in the Museum of Fine Arts Boston 8 In the Middle Kingdom 2050 1652 BC it continued to be used as a pigment in the decoration of tombs wall paintings furnishings and statues and by the New Kingdom 1570 1070 BC began to be more widely used in the production of numerous objects Its use continued throughout the Late period and Greco Roman period only dying out in the fourth century AD when the secret to its manufacture was lost 9 No written information exists in ancient Egyptian texts about the manufacture of Egyptian blue in antiquity and it was first mentioned only in Roman literature by Vitruvius during the first century BC 10 He refers to it as caeruleum and describes in his work De architectura how it was produced by grinding sand copper and natron and heating the mixture shaped into small balls in a furnace Lime is necessary for the production as well but probably lime rich sand was used Theophrastus gives it the Greek term kyanos kyanos blue 11 which originally probably referred to lapis lazuli Finally only at the beginning of the nineteenth century was interest renewed in learning more about its manufacture when it was investigated by Humphry Davy in 1815 12 and others such as W T Russell and F Fouque Composition and manufacture editSeveral experiments have been carried out by scientists and archaeologists interested in analyzing the composition of Egyptian blue and the techniques used to manufacture it It is now generally regarded as a multiphase material that was produced by heating together quartz sand a copper compound calcium carbonate and a small amount of an alkali ash from salt tolerant halophyte plants or natron at temperatures ranging between 800 and 1 000 C 1 470 and 1 830 F depending on the amount of alkali used for several hours 13 The result is cuprorivaite or Egyptian blue carbon dioxide and water vapor Cu2CO3 OH 2 8 SiO2 2 CaCO3 2 CaCuSi4O10 3 CO2 H2O In its final state Egyptian blue consists of rectangular blue crystals together with unreacted quartz and some glass From the analysis of a number of samples from Egypt and elsewhere the weight percentage of the materials used to obtain Egyptian blue in antiquity was determined usually to range within these amounts 13 60 70 silica SiO2 7 15 calcium oxide CaO 10 20 copper II oxide CuO To obtain theoretical cuprorivaite where only blue crystals occur with no excess of unreacted quartz or formation of glass these percentages would need to be used 13 64 silica 15 calcium oxide 21 copper oxideHowever none of the analyzed samples from antiquity was made of this definitive composition as all had excesses of silica together with an excess of either CuO or CaO 14 This may have been intentional an increase in the alkali content results in the pigment containing more unreacted quartz embedded in a glass matrix which in turn results in a harder texture 13 Lowering the alkali content less than 1 though does not allow glass to form and the resultant Egyptian blue is softer with a hardness of 1 2 Mohs 14 In addition to the way the different compositions influenced texture the way Egyptian blue was processed also had an effect on its texture in terms of coarseness and fineness Following a number of experiments Tite et al concluded that for fine textured Egyptian blue two stages were necessary to obtain uniformly interspersed crystals First the ingredients are heated and the result is a coarse textured product This is then ground to a fine powder and water is added The paste is then reshaped and fired again at temperatures ranging between 850 and 950 C for one hour These two stages possibly were needed to produce a paste that was fine enough for the production of small objects Coarse textured Egyptian blue though would not have gone through the second stage Since it usually is found in the form of slabs in the dynastic periods and balls in the Greco Roman period these either could have been awaiting to be processed through a second stage where they would be ground and finely textured or they would have been ground for use as a blue pigment 13 The shade of blue reached was also related to the coarseness and fineness of Egyptian blue as it was determined by the degree of aggregation of the Egyptian blue crystals Coarse Egyptian blue was relatively thick in form due to the large clusters of crystals which adhere to the unreacted quartz This clustering results in a dark blue color that is the appearance of coarse Egyptian blue Alternatively fine textured Egyptian blue consists of smaller clusters that are uniformly interspersed between the unreacted quartz grains and tends to be light blue in color 13 Diluted light blue though is used to describe the color of fine textured Egyptian blue that has a large amount of glass formed in its composition which masks the blue color and gives it a diluted appearance It depends on the level of alkali added to the mixture so with more alkali more glass formed and the more diluted the appearance 13 This type of Egyptian blue is especially evident during the eighteenth dynasty and later and probably is associated with the surge in glass technology at this time 6 If certain conditions were not met the Egyptian blue would not be satisfactorily produced For example if the temperatures were above 1050 C it would become unstable 15 If too much lime was added wollastonite CaSiO3 forms and gives the pigment a green color Too much of the copper ingredients results in excesses of copper oxides cuprite and tenorite 15 Sources editThe main component of Egyptian blue was the silica and quartz sand found adjacent to the sites where Egyptian blue was being manufactured may have been its source 13 although no concrete evidence supports this hypothesis The only evidence cited is by Jakcsh et al who found crystals of titanomagnetite a mineral found in desert sand in samples collected from the tomb of Sabni sixth dynasty Its presence in Egyptian blue indicates that quartz sand rather than flint or chert was used as the silica source This contrasts with the source of silica used for glass making at Qantir New Kingdom Ramesside site which is quartz pebbles and not sand 16 It is believed that calcium oxide was not added intentionally on its own during the manufacture of Egyptian blue but introduced as an impurity in the quartz sand and alkali 13 As to whether the craftsmen involved in the manufacture realized the importance of adding lime to the Egyptian blue mixture is not clear from this The source of copper could have been either a copper ore such as malachite filings from copper ingots or bronze scrap and other alloys Before the New Kingdom evidence is scarce as to which copper source was being used but it is believed to have been copper ores During the New Kingdom evidence has been found for the use of copper alloys such as bronze due to the presence of varying amounts of tin arsenic or lead found in the Egyptian blue material 15 The presence of tin oxide could have come from copper ores that contained tin oxide and not from the use of bronze However no copper ores have been found with these amounts of tin oxide 15 Why a switch from the use of copper ores in earlier periods to the use of bronze scrap during the Late Bronze Age is unclear as yet The total alkali content in analyzed samples of Egyptian blue is greater than 1 suggesting the alkali was introduced deliberately into the mixture and not as an impurity from other components Sources of alkali either could have been natron from areas such as Wadi Natroun and El Kab or plant ash By measuring the amounts of potash and magnesia in the samples of Egyptian blue it is generally possible to identify which source of alkali had been used since the plant ash contains higher amounts of potash and magnesia than the natron However due to the low concentration of alkali in Egyptian blue which is a mere 4 or less compared to glass for example which is at 10 20 identifying the source is not always easy The alkali source likely was natron 14 although the reasons for this assumption are unclear However analysis by Jaksch et al of various samples of Egyptian blue identified variable amounts of phosphorus up to 2 wt suggesting the alkali source used was in actuality plant ash and not natron 15 Since the glass industry during the Late Bronze Age used plant ash as its source of alkali 17 a link in terms of the alkali used for Egyptian blue before and after the introduction of the glass industry might have been possible Archaeological evidence editAmarna edit In the excavations at Amarna Lisht and Malkata at the beginning of the twentieth century Petrie uncovered two types of vessels that he suggested were used in antiquity to make Egyptian blue bowl shaped pans and cylindrical vessels or saggers In recent excavations at Amarna by Barry Kemp 1989 very small numbers of these fritting pans were uncovered although various remaining pieces of Egyptian blue cake were found which allowed the identification of five different categories of Egyptian blue forms and the vessels associated with them large round flat cakes large flat rectangular cakes bowl shaped cakes small sack shaped pieces and spherical shapes 18 No tin was found in the samples analyzed which the authors suggest is an indication that use of scrap copper was possible instead of bronze 19 Qantir edit In the 1930s Mahmud Hamza excavated a number of objects related to the production of Egyptian blue at Qantir such as Egyptian blue cakes and fragments in various stages of production 20 providing evidence that Egyptian blue was actually produced at the site Recent excavations at the same site uncovered a large copper based industry with several associated crafts namely bronze casting red glass making faience production and Egyptian blue 20 Ceramic crucibles with adhering remains of Egyptian blue were found in the excavations suggesting again it had been manufactured on site These Egyptian blue cakes possibly were later exported to other areas around the country to be worked as a scarcity of finished Egyptian blue products existed on site For example Egyptian blue cakes were found at Zawiyet Umm el Rakham a Ramesside fort near the Libyan coast indicating in fact that the cakes were traded and worked at and reshaped away from their primary production site 20 Connections with other vitreous material and with metals edit nbsp Blue faience saucer and stand New Kingdom 1400 1325 BC Egyptian blue is closely related to the other vitreous materials produced by the ancient Egyptians namely glass and Egyptian faience and it is possible that the Egyptians did not employ separate terms to distinguish the three products from one another 9 Although it is easier to distinguish between faience and Egyptian blue due to the distinct core of faience objects and their separate glaze layers it sometimes is difficult to differentiate glass from Egyptian blue due to the very fine texture that Egyptian blue occasionally could have This is especially true during the New Kingdom as Egyptian blue became more refined and glassy and continued as such into the Greco Roman period 21 Since Egyptian blue like faience is a much older technology than glass which only begins during the reign of Thutmose III 1479 1425 BC changes in the manufacture of Egyptian blue undoubtedly were associated with the introduction of the glass industry Analysis of the source of copper used in the manufacture of Egyptian blue indicates a relationship with the contemporaneous metal industry Whereas in the earlier periods it is most probable that copper ores were used during the reign of Tutmosis III the copper ore is replaced by the use of bronze filings 6 This has been established by the detection of a specific amount of tin oxide in Egyptian blue which only could have resulted from the use of tin bronze scraps as the source of copper which coincides with the time when bronze became widely available in ancient Egypt Occurrences outside Egypt editEgyptian blue was found in Western Asia during the middle of third millennium BC in the form of small artifacts and inlays but not as a pigment 6 It was found in the Mediterranean area at the end of the Middle Bronze Age and traces of tin were found in its composition suggesting the use of bronze scrap instead of copper ore as the source of copper 6 During the Roman period use of Egyptian blue was extensive as a pot containing the unused pigment found in 1814 in Pompeii illustrates It was also found as unused pigment in the tombs of a number of painters Etruscans also used it in their wall paintings The related Chinese blue has been suggested as having Egyptian roots Later Raphael used Egyptian blue in his Triumph of Galatea 22 Roman production of Egyptian blue edit nbsp Raman microspectroscopic phase distribution map of a paint layer from the church of St Peter above Gratsch showing several minor major and trace compounds of Egyptian blue 23 Around the turn of the eras Roman sources report that a certain Vestorius transferred the production technology from Alexandria to Pozzuoli near Naples Campania Southern Italy 24 In fact archaeological evidences confirm production sites in the northern Phlegraean Fields and seem to indicate a monopoly in the manufacture and trade of pigment spheres Due to its almost exclusive use Egyptian blue is the blue pigment par excellence of Roman antiquity its art technological traces vanish in the course of the Middle Ages 23 In 2021 Early Medieval Egyptian blue fifth sixth century AD was identified on a monochrome blue mural fragment from the church of St Peter above Gratsch South Tyrol Northern Italy By a new analytical approach based on Raman microspectroscopy 28 different minerals with contents from the percent range down to 100 ppm were identified Inclusion of knowledge from neighbouring disciplines made possible to read out the information about the type and provenance of the raw materials synthesis and application of the pigment and ageing of the paint layer preserved in the previously not accessible trace components and thus to reconstruct the individual biography of the Egyptian blue from St Peter This paradigm shift in the research history of Egyptian blue provided natural scientific evidences for the production in the northern Phlegraean fields agreement with trace minerals found in the beach sands at the Gulf of Gaeta the use of a sulphidic copper ore instead of often mentioned metallic copper or bronze and plant ash as flux in the raw material mixture Furthermore indications for a synthesis predominated by solid state reactions were found while the melting of the raw materials into glass most likely played a negligible role 23 A follow up study on Roman Imperial pigment balls excavated in Aventicum and Augusta Raurica Switzerland first to third century AD confirmed the results in 2022 The consistent composition of around 40 identified minerals establishes a connection to the northern Phlegraean Fields a sulphidic copper ore and plant ash have also left their marks Thus the Roman production monopoly probably existed for centuries In addition the analyses revealed unwanted by products of the synthesis locally limited to microparticles on the sphere s surfaces which can be traced back to suboptimal burning times or mixing ratios respectively a cuprorivaite with crystal defects in its layer structure and a copper bearing green glass phase characterised by Raman spectroscopy for the first time 25 Modern applications editEgyptian blue s extremely powerful and long lived infrared luminescence under visible light has enabled its presence to be detected on objects which appear unpainted to the human eye 26 This property has also been used to identify traces of the pigment on paintings produced as late as the sixteenth century long after its use was presumed to have died out 27 The luminescence in the near infrared where neither fat nor hemoglobin show high absorption coefficients in conjunction with the capacity of Egyptian blue to delaminate by splitting into nanosheets after immersion in water also indicates it may have several high technology applications such as in biomedicine e g bioimaging telecommunications laser technology and security inks 28 29 30 Researchers at the Lawrence Berkeley National Laboratory discovered that Egyptian blue pigment absorbs visible light and emits light in the near infrared range This suggests that Egyptian blue pigment could be used in construction materials designed to cool rooftops and walls in sunny climates and for tinting glass to improve photovoltaic cell performance 31 32 33 See also editLazurite Alumino silicate mineral whose blue colour is due to a sulfide species and not copper Lapis lazuli Metamorphic rock containing lazurite prized for its intense blue color Persian blue Blue colour associated with Persian pottery Han purple and Han blue Artificial barium copper silicate pigments developed in ancient China during the Han dynasty Maya blue Azure blue pigment made in pre Columbian Mesoamerica Prussian blue Synthetic pigment Ancient Chinese glass List of colors List of inorganic pigments Egyptian blue shades Variety of the color blue Blue pigmentsReferences edit Cuprorivaite mindat org a b c Eastaugh Nicholas Walsh Valentine Chaplin Tracey Siddall Ruth 2004 Egyptian blue The pigment compendium Optical microscopy of historical pigments Oxford UK Elsevier Butterworth Heinemann pp 147 148 Maerz and Paul A Dictionary of Color New York 1930 McGraw Hill Page 194 Color Sample of Sunset Page 93 Plate 35 Color Sample L8 McCouat Philip 2018 Egyptian blue The colour of technology artinsociety com Journal of Art in Society Archived from the original on 2019 03 28 Retrieved 2019 05 29 Pages Camagna S 1998 Bleu et vert egyptiens en question vocabulaire et analyses In Colinart S Menu M eds La couleur dans la peinture et l emaillage de l Egypte Ancienne CUEBC Ravello 20 22 March 1997 Edipuglia Bari pp 51 59 a b c d e Lee L Quirke S 2000 Painting materials In P Nicholson I Shaw eds Ancient Egyptian materials and technology Cambridge University Press ISBN 978 0 521 45257 1 Nicholson P T amp Henderson J 2000 Glass In P Nicholson and I Shaw eds Ancient Egyptian materials and technology Cambridge Cambridge University Press ISBN 0 521 45257 0 Lorelei H Corcoran The Color Blue as an Animator in Ancient Egyptian Art in Rachael B Goldman ed Essays in Global Color History Interpreting the Ancient Spectrum New Jersey Gorgias Press 2016 pp 59 82 a b Chase W T 1971 Egyptian blue as a pigment and ceramic material In R Brill ed Science and Archaeology Cambridge MMassachusetts MIT Press ISBN 0 262 02061 0 Vitruvius De Architectura Book VII Chapter 11 Theophrastus De Lapidibus On Stones section 55 Sir Humphry Davy 1815 Some experiments and observations on the colours used in painting by the ancients Philosophical Transactions of the Royal Society of London vol 105 pages 97 124 Reprinted in The Collected Works of Sir Humphry Davy London England Smith Elder and Co 1840 vol VI pp 131 159 a b c d e f g h i Tite M S Bimson M amp Cowell M R 1987 The technology of Egyptian blue In M Bimson I C Freestone eds Early Vitreous materials British Museum occasional paper 56 London British Museum ISBN 978 0 86159 056 8 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link a b c Tite M S Bimson M amp Cowell M R 1984 Technological examination of Egyptian blue In J B Lambert ed Archaeological Chemistry III Advances in chemistry series 205 Washington DC American Chemical Society ISBN 978 0 8412 0767 7 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link a b c d e Jaksch H Seipel W Weiner K L amp El Goresy A 1983 Egyptian Blue Cuprorivaite a window to Ancient Egyptian technology Die Naturwissenschaften 70 11 525 535 Bibcode 1983NW 70 525J doi 10 1007 BF00376668 S2CID 2457936 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Rehren Th Pusch E B 2005 Late Bronze Age glass production at Qantir Piramesses Egypt Science 308 5729 1756 1758 Bibcode 2005Sci 308 1756R doi 10 1126 science 1110466 PMID 15961663 S2CID 26214625 Rehren Th 2001 Aspects of the production of cobalt blue glass in Egypt Archaeometry 43 4 483 489 doi 10 1111 1475 4754 00031 Kemp B 1989 Amarna Reports V London Egypt Exploration Society ISBN 0 85698 109 5 Weatherhead F amp Buckley A 1989 Artists pigments from Amarna In B Kemp ed Amarna Reports V 202 239 London Egypt Exploration Society ISBN 0 85698 109 5 a b c Rehren Th Pusch E B Herold A 2001 Problems and possibilities in workshop reconstruction Qantir and the organization of LBA glass working sites In A J Shortland ed The social context of technological change Egypt and the Near East 1650 1550 BC Proceedings of a conference held at St Edmund Hall Oxford 12 14 September 2000 Oxford Oxbow Books ISBN 978 1 84217 050 2 Nicholson P T amp Peltenburg E 2000 Egyptian faience In In P Nicholson and I Shaw eds Ancient Egyptian materials and technology Cambridge Cambridge University Press ISBN 0 521 45257 0 Ancient Hue Detected in Renaissance Painting Archaeology Magazine www archaeology org Retrieved 2021 10 12 a b c Petra Dariz Thomas Schmid 2021 Trace compounds in Early Medieval Egyptian blue carry information on provenance manufacture application and ageing Scientific Reports 11 11296 11296 Bibcode 2021NatSR 1111296D doi 10 1038 s41598 021 90759 6 ISSN 2045 2322 PMC 8163881 PMID 34050218 The recipes for blue sky blue were first discovered in Alexandria and subsequently Vestorius began to manufacture it in Puteoli as well from Vitruvius Marcus Vitruvius Pollio De architectura libri decem Liber VII Caput Xl first century A D English translation Ingrid D Rowland 1999 Chapter 11 Blue Ten Books on Architecture Book 7 Finishing Cambridge Cambridge University Press p 94 ISBN 978 0 511 84095 1 Petra Dariz Thomas Schmid 2022 Raman focal point on Roman Egyptian blue elucidates disordered cuprorivaite green glass phase and trace compounds Scientific Reports 12 15596 15596 Bibcode 2022NatSR 1215596D doi 10 1038 s41598 022 19923 w ISSN 2045 2322 PMC 9481618 PMID 36114229 Verri G June 2009 The spatially resolved characterisation of Egyptian blue Han blue and Han purple by photo induced luminescence digital imaging Analytical and Bioanalytical Chemistry Vol 394 Issue 4 pp 1011 1021 McCouat P Egyptian blue the colour of technology Journal of Art in Society Accorsi G et al 2009 The exceptional near infrared luminescence of cuprorivaite Egyptian blue Chemical Communications Issue 23 p 3392 Bredal Jorgensen J et al September 2011 Striking presence of Egyptian blue identified in a painting by Giovanni Battista Benvenuto from 1524 Analytical and Bioanalytical Chemistry Vol 401 Issue 4 p 1433 Gabriele Selvaggio Alexey Chizhik Robert Nissler llyas Kuhlemann Daniel Meyer Loan Vuong Helen Preiss Niklas Herrmann Florian A Mann Zhiyi Lv Tabea A Oswald Alexander Spreinat Luise Erpenbeck Jorg Grosshans Volker Karius Andreas Janshoff Juan Pablo Giraldo Sebastian Kruss 2020 Exfoliated near infrared fluorescent silicate nanosheets for bio photonics In Nature Communications Vol 11 No 1495 doi 10 1038 s41467 020 15299 5 Egyptian Blue for Energy Efficiency Lawrence Berkeley Laboratory Heat Island Group October 9 2018 Retrieved 2018 10 14 World s 1st artificially made pigment Egyptian blue can help produce solar energy India Today October 11 2018 Retrieved October 14 2018 Scientists give solar PV a paint job PV magazine USA October 9 2018 Retrieved October 14 2018 Further reading editDayton J 1978 Minerals Metals Glazing amp Man or Who Was Sesostris I London Harrap ISBN 0 245 52807 5 Lucas A amp Harris J R 1948 1999 Ancient Egyptian Materials and Industries Dover books on Egypt Mineola N Y Dover ISBN 0 486 40446 3 Noll W 1981 Mineralogy and technology of the painted ceramics of ancient Egypt In M J Huges ed Scientific studies in ancient ceramics Occasional paper 19 London British Museum ISBN 0 86159 018 X Rehren Th amp Pusch E B amp Herold A 1998 Glass coloring works within a copper centered industrial complex in Late Bronze Age Egypt In McCray P ed The prehistory and history of glassmaking technology Ceramics and Civilization 8 Westerville OH American Ceramic Society ISBN 1 57498 041 6 Riederer J 1997 Egyptian Blue In E W Fitzhugh ed Artists pigments 3 23 45 Oxford university Press ISBN 0 89468 256 3 Tite M S 1985 Egyptian blue faience and related materials technological investigations In R E Jones amp H W Catling eds Science in Archaeology Proceedings of a Meeting Held at the British School at Athens January 1985 London Leopard s Head ISBN 0 904887 02 2 Warner T E 2011 Artificial Cuprorivaite CaCuSi4O10 Egyptian Blue by a Salt Flux Method In Terence E Warner Synthesis Properties and Mineralogy of Important Inorganic Materials 26 49 Chichester Wiley ISBN 978 0 470 74611 0 Wiedemann H G Bayer G amp Reller A 1998 Egyptian blue and Chinese blue Production technologies and applications of two historically important blue pigments In S Colinart amp M Menu eds La couleur dans la peinture et lemaillage de l Egypte Ancienne Scienze e materiali del patrimonio culturale 4 Bari Edipuglia ISBN 88 7228 201 2 External links editEgyptian blue ColourLex Egyptian Blue Pigments through the ages Retrieved from https en wikipedia org w index php title Egyptian blue amp oldid 1185848339, wikipedia, wiki, book, books, library,

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