Ceramic glaze

Composite body, painted, and glazed bottle. Iran, 16th century (Metropolitan Museum of Art)
Detail of dripping rice-straw ash glaze (top), Japan, 1852

Ceramic glaze is an impervious layer or coating of a vitreous substance which has been fused to a ceramic body through firing. Glaze can serve to color, decorate or waterproof an item.[1] Glazing renders earthenware vessels suitable for holding liquids, sealing the inherent porosity of unglazed biscuit earthenware. It also gives a tougher surface. Glaze is also used on stoneware and porcelain. In addition to their functionality, glazes can form a variety of surface finishes, including degrees of glossy or matte finish and color. Glazes may also enhance the underlying design or texture either unmodified or inscribed, carved or painted.

Most pottery produced in recent centuries has been glazed, other than pieces in unglazed terracotta, biscuit porcelain or some other types. Tiles are almost always glazed on the surface face, and modern architectural terracotta is very often glazed. Glazed brick is also common. Domestic sanitary ware is invariably glazed, as are many ceramics used in industry, for example ceramic insulators for overhead power lines.

The most important groups of traditional glazes, named after their main ceramic fluxing agent, are:

Modern materials technology has invented new vitreous glazes that do not fall into these traditional categories.

Composition

Glazes need to include a ceramic flux which functions by promoting partial liquefaction in the clay bodies and the other glaze materials. Fluxes lower the high melting point of the glass formers silica, and sometimes boron trioxide. These glass formers may be included in the glaze materials, or may be drawn from the clay beneath.

Raw materials of ceramic glazes generally include silica, which will be the main glass former. Various metal oxides, such as sodium, potassium, and calcium, act as flux and therefore lower the melting temperature. Alumina, often derived from clay, stiffens the molten glaze to prevent it from running off the piece.[2] Colorants, such as iron oxide, copper carbonate, or cobalt carbonate,[2] and sometimes opacifiers like tin oxide or zirconium oxide, are used to modify the visual appearance of the fired glaze.

Process

Glaze may be applied by dry-dusting a dry mixture over the surface of the clay body or by inserting salt or soda into the kiln at high temperatures to create an atmosphere rich in sodium vapor that interacts with the aluminium and silica oxides in the body to form and deposit glass, producing what is known as salt glaze pottery. Most commonly, glazes in aqueous suspension of various powdered minerals and metal oxides are applied by dipping pieces directly into the glaze. Other techniques include pouring the glaze over the piece, spraying it onto the piece with an airbrush or similar tool, or applying it directly with a brush or other tool.

To prevent the glazed article from sticking to the kiln during firing, either a small part of the item is left unglazed, or it's supported on small refractory supports such as kiln spurs and Stilts that are removed and discarded after the firing. Small marks left by these spurs are sometimes visible on finished ware.

Decoration applied under the glaze on pottery is generally referred to as underglaze. Underglazes are applied to the surface of the pottery, which can be either raw, "greenware", or "biscuit"-fired (an initial firing of some articles before the glazing and re-firing).[3][4][5] A wet glaze—usually transparent—is applied over the decoration. The pigment fuses with the glaze, and appears to be underneath a layer of clear glaze. An example of underglaze decoration is the well-known "blue and white" porcelain famously produced in England, the Netherlands, China, and Japan. The striking blue color uses cobalt as cobalt oxide or cobalt carbonate.[6]

Sancai lead-glazed figure of heavenly guardian, Tang dynasty

Decoration applied on top of a layer of glaze is referred to as overglaze. Overglaze methods include applying one or more layers or coats of glaze on a piece of pottery or by applying a non-glaze substance such as enamel or metals (e.g., gold leaf) over the glaze.

Overglaze colors are low-temperature glazes that give ceramics a more decorative, glassy look. A piece is fired first, this initial firing being called the glost firing, then the overglaze decoration is applied, and it is fired again. Once the piece is fired and comes out of the kiln, its texture is smoother due to the glaze.

History

Historically, glazing of ceramics developed rather slowly, as appropriate materials needed to be discovered, and also firing technology able to reliably reach the necessary temperatures was needed.

Glazed brick goes back to the Elamite Temple at Chogha Zanbil, dated to the 13th century BC. The Iron Pagoda, built in 1049 in Kaifeng, China, of glazed bricks is a well-known later example.[7]

Lead glazed earthenware was probably made in China during the Warring States Period (475 – 221 BCE), and its production increased during the Han Dynasty. High temperature proto-celadon glazed stoneware was made earlier than glazed earthenware, since the Shang Dynasty (1600 – 1046 BCE). [8]

During the Kofun period of Japan, Sue ware was decorated with greenish natural ash glazes. From 552 to 794 AD, differently colored glazes were introduced. The three colored glazes of the Tang Dynasty were frequently used for a period, but were gradually phased out; the precise colors and compositions of the glazes have not been recovered. Natural ash glaze, however, was commonly used throughout the country.

In the 13th century, flower designs were painted with red, blue, green, yellow and black overglazes. Overglazes became very popular because of the particular look they gave ceramics.

From the eighth century, the use of glazed ceramics was prevalent in Islamic art and Islamic pottery, usually in the form of elaborate pottery.[9] Tin-opacified glazing was one of the earliest new technologies developed by the Islamic potters. The first Islamic opaque glazes can be found as blue-painted ware in Basra, dating to around the 8th century. Another significant contribution was the development of stoneware, originating from 9th century Iraq.[10] Other centers for innovative ceramic pottery in the Islamic world included Fustat (from 975 to 1075), Damascus (from 1100 to around 1600) and Tabriz (from 1470 to 1550).[11]

Environmental impact

As of 2012, over 650 ceramic manufacturing establishments were reported in the United States.[1] Floor tile, wall tile, sanitary-ware, bathroom accessories, kitchenware, and tableware are all potential ceramic-containing products that are available for consumers.[12] Heavy metals are dense metals used in glazes to produce a particular color or texture.[4] Glaze components are more likely to be leached into the environment when non-recycled ceramic products are exposed to warm or acidic water.[13] Leaching of heavy metals occurs when ceramic products are glazed incorrectly or damaged.[13] Lead and chromium are two heavy metals commonly used in ceramic glazes that are heavily monitored by government agencies due to their toxicity and ability to bioaccumulate.[13][14]

Metal oxide chemistry

Metals used in ceramic glazes are typically in the form of metal oxides.

Lead(II) oxide

Ceramic manufacturers primarily use lead(II) oxide (PbO) as a flux for its low melting range, wide firing range, low surface tension, high index of refraction, and resistance to devitrification.[15] Nitrogen dioxide (NO
2
) plays a role in the mobilization of lead in the environment. In polluted environments, nitrogen dioxide reacts with water (H
2
O
) to produce nitrous acid (HNO
2
) and nitric acid (HNO
3
).[14]

H
2
O
+ 2NO
2
HNO
2
+ HNO
3

Lead(II) nitrate (Pb(NO
3
)
2
) forms when lead(II) oxide (PbO) of leaded glazes is exposed to nitrogen dioxide (NO
2
) found in polluted air.[9][14]

PbO + 2HNO
3
Pb(NO
3
)
2
+ H
2
O

The lead(II) nitrate product readily dissolves in water to form lead ions (Pb2+
) and nitrate ions (NO
3
):[14]

Pb(NO
3
)
2
Pb2+
+ 2NO
3

When consumed, lead interferes with normal biochemistry by forming stable chemical bonds with amino acids of proteins.[16] When lead is converted to its stable oxidation state (Pb2+), it reacts with the sulphydryl groups (-SH) of cysteine.[15] Proteins bound to lead are unable to be used up by biological processes and remain in the tissue of plants and animals.[15]

The reaction between a lead ion (Pb2+
) and the sulfhydryl (–SH) groups on a protein.

Lead exposure is strongly linked to negative renal effects in animals and humans.[11] Renal deficiency was observed in Wistar rats after two weeks of orally ingesting lead acetate.[16]

Chromium(III) oxide

Chromium(III) oxide (Cr
2
O
3
) is used as a colorant in ceramic glazes. Chromium(III) oxide can undergo a reaction with calcium oxide (CaO) and atmospheric oxygen in temperatures reached by a kiln to produce calcium chromate (CaCrO
4
). The oxidation reaction changes chromium from its +3 oxidation state to its +6 oxidation state.[17] Chromium(VI) is very soluble and the most mobile out of all the other stable forms of chromium.[18]

Cr
2
O
3
+ 2CaO + 32O
2
CaCrO
4
[17]

Chromium may enter water systems via industrial discharge. Chromium(VI) can enter the environment directly or oxidants present in soils can react with chromium(III) to produce chromium(VI). Plants have reduced amounts of chlorophyll when grown in the presence of chromium(VI).[18]

Prevention

Chromium oxidation during manufacturing processes can be reduced with the introduction of compounds that bind to calcium.[17] Ceramic industries are reluctant to use lead alternatives since leaded glazes provide products with a brilliant shine and smooth surface. The United States Environmental Protection Agency has experimented with a dual glaze, barium alternative to lead, but they were unsuccessful in achieving the same optical effect as leaded glazes.

See also

Footnotes

  1. 1 2 Division, Company Statistics. "Statistics of U.S. Businesses Main Page". www.census.gov. Archived from the original on 2015-11-26. Retrieved 2015-11-27.
  2. 1 2 Madan, Gaurav (2005). S.Chands Success Guide (Q&A) Inorganic Chemistry. S. Chand Publishing. ISBN 9788121918572.
  3. "Cleaning Biscuit Fired Ceramic Ware" Hulse D.K, Barnett W.C. UK Pat.Appl.GB2287643A
  4. 1 2 Denio, Allen A. (1980-04-01). "Chemistry for potters". Journal of Chemical Education. 57 (4). doi:10.1021/ed057p272.
  5. "Roller Kilns For The Fast Biscuit And Glost Firing Of Porcelain" Rodriguez Mamolar M.J., De La Fuente Revuelta J. Ceram. Inf.(Spain) 20, No.202. 1994. Pg. 25–27
  6. 'Ceramics Glaze Technology.' J.R.Taylor & A.C.Bull. The Institute Of Ceramics & Pergamon Press. Oxford. 1986
  7. Daiheng, Gao (2002). Chinese Architecture – The Lia, Song, Xi Xia and Jin Dynasties (English ed.). Yale University Press. pp. 166, 183. ISBN 0-300-09559-7.
  8. Zhiyan, Li (2002). Chinese Ceramics -- From the Paleolithic Period through the Qing Dynasty (English ed.). New York & London, Beijing: Yale University Press, Foreign Languages Press. pp. 144, 145, 152. ISBN 978-0-300-11278-8.
  9. 1 2 Environment, Department of the. "Nitrogen dioxide (NO2)". www.environment.gov.au. Retrieved 2015-11-09.
  10. Mason (1995), p. 5
  11. 1 2 Missoun, F., M. Slimani, and A. Aoues. "Toxic Effect of Lead on Kidney Function in Rat Wistar." African Journal of Biochemistry Research 4.2 (2010): 21–27. Print.
  12. Environmental Protection Agency. (February 2003) Economic Impact Analysis of the Clay Ceramics Manufacturing NESHAP: Final Rule (EPA Publication No. EPA-452/R-03-007). Research Triangle Park, NC: Environmental Protection Agency.
  13. 1 2 3 Omolaoye, J.A,, A. Uzairu, and C.E. Gimba. "Heavy Metal Assessment of Some Ceramic Products Imported into Nigeria from China." Archives of Applied Science Research 2.5 (2010): 120-25. Web. 15 Oct. 2015
  14. 1 2 3 4 Baltrusaitis, Jonas; Chen, Haihan; Rubasinghege, Gayan; Grassian, Vicki H. (2012-12-04). "Heterogeneous Atmospheric Chemistry of Lead Oxide Particles with Nitrogen Dioxide Increases Lead Solubility: Environmental and Health Implications". Environmental Science & Technology. 46 (23): 12806–12813. doi:10.1021/es3019572. ISSN 0013-936X. PMC 3518381. PMID 23057678.
  15. 1 2 3 Lehman, Richard. Lead Glazes for Ceramic Foodware. 1st ed. Research Triangle Park: International Lead Management Center, 2002. International Lead Management Center
  16. 1 2 Duruibe, J.O., M.O.C. Ogwuegbu, and J.N. Egwurugwu. "Heavy Metal Pollution and Human Biotoxic Effects." International Journal of Physical Sciences 2.5 (2007): 112-18.
  17. 1 2 3 Verbinnen, Bram; Billen, Pieter; Van Coninckxloo, Michiel; Vandecasteele, Carlo (2013-06-04). "Heating Temperature Dependence of Cr(III) Oxidation in the Presence of Alkali and Alkaline Earth Salts and Subsequent Cr(VI) Leaching Behavior". Environmental Science & Technology. 47 (11): 5858–5863. doi:10.1021/es4001455. ISSN 0013-936X.
  18. 1 2 Oliveira, Helena (2012-05-20). "Chromium as an Environmental Pollutant: Insights on Induced Plant Toxicity". Journal of Botany. 2012: 1–8. doi:10.1155/2012/375843.

References

  • Hamer, Frank and Janet. The Potter's Dictionary of Materials and Techniques. A & C Black Publishers, Limited, London, England, Third Edition 1991. ISBN 0-8122-3112-0.
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