Lead glass is a variety of glass in which lead replaces the calcium content of a typical potash glass. Lead glass contains typically 18–40 weight% lead(II) oxide (PbO), while modern lead crystal, historically also known as flint glass due to the original silica source, contains a minimum of 24% PbO. Lead glass is desirable owing to its decorative properties.
Technically, the term crystal is not applied to glass, as glass, by definition, lacks a crystalline structure. The use of the term lead crystal remains popular for historical and commercial reasons, and originally stems from the invention in 1674 by Englishman George Ravenscroft 1632-1683, that by adding lead oxide in quantities of between 10 and 30% the appearance of the glass improved and it was easier to melt using sea-coal as a furnace fuel, and had a longer "working period", and the Venetian use of the word cristallo to describe the rock crystal imitated by Murano glassmakers. This naming convention has been maintained to the present day to describe decorative hollow-ware.
The addition of lead oxide to glass raises its refractive index and lowers its working temperature and viscosity. The attractive optical properties of lead glass result from the high content of the heavy metal lead. The high atomic number of lead also raises the density of the material, since lead has a very high atomic weight of 207.2, versus 40.08 for calcium. The density of soda glass is 2.4 g/cm3 or below, while typical lead crystal has a density of around 3.1 g/cm3 and high-lead glass can be over 4.0 g/cm3 or even up to 5.9 g/cm3.
The brilliance of lead crystal relies on the high refractive index caused by the lead content. Ordinary glass has a refractive index of n = 1.5, while the addition of lead produces a range up to 1.7. This heightened refractive index also correlates with increased dispersion, which measures the degree to which a medium separates light into its component spectra, as in a prism. Crystal cutting techniques exploit these properties to create a brilliant, sparkling effect as each cut facet reflects and transmits light through the object. The high refractive index is useful for lens making, since a given focal length can be achieved with a thinner lens. However, the dispersion must be corrected by other components of the lens system if it is to be achromatic.
The addition of lead oxide to potash glass also reduces its viscosity, rendering it more fluid than ordinary soda glass above softening temperature (about 600 °C), with a working point of 800 °C. The viscosity of glass varies radically with temperature, but that of lead glass is roughly 100 times less than that of ordinary soda glasses across working temperature ranges (up to 1100 °C). From the glassmaker’s perspective, this results in two practical developments. First, lead glass may be worked at a lower temperature, leading to its use in enamelling, and second, clear vessels may be made free from trapped air bubbles with considerably less difficulty than with ordinary glasses, allowing the manufacture of perfectly clear, flawless objects. When tapped, lead crystal makes a ringing sound, unlike ordinary glasses. Consumers still rely on this property to distinguish it from cheaper glasses. Since the potassium ions are bound more tightly in a lead-silica matrix than in a soda-lime glass, the glass when struck absorbs less energy. This causes the glass to oscillate, thereby producing its characteristic sound. Lead also increases the solubility of tin, copper, and antimony, leading to its use in colored enamels and glazes. The low viscosity of lead glass melt is the reason for typically high lead oxide content in the glass solders.
The presence of lead is used in glasses absorbing gamma radiation and X-rays, used in radiation shielding (e.g. in cathode ray tubes, where lowering the exposure of the viewer to soft X-rays is of concern).
The high ionic radius of the Pb2+ ion renders it highly immobile in the matrix and hinders the movement of other ions; lead glasses therefore have high electrical resistance, about two orders of magnitude higher than soda-lime glass (108.5 vs 106.5 Ohm·cm, DC at 250 °C). Lead-containing glass is therefore frequently used in light fixtures.
use PbO (wt.%) Household "crystal" leaded glass 18–38 Ceramic glazes and vitreous enamels 16–35 High refractive index optical glasses 4–65 Radiation shielding 2–28 High electrical resistance 20–22 Glass solders and sealants 56–77
Lead may be introduced into glass either as an ingredient of the primary melt or added to preformed leadless glass or frit. The lead oxide used in lead glass could be obtained from a variety of sources. In Europe, galena, lead sulfide, was widely available, which could be smelted to produce metallic lead. The lead metal would be calcined to form lead oxide by roasting it and scraping off the litharge. In the medieval period lead metal could be obtained through recycling from abandoned Roman sites and plumbing, even from church roofs. Metallic lead was demanded in quantity for silver cupellation, and the resulting litharge could be used directly by glassmakers. Lead was also used for ceramic lead glazes. This material interdependence suggests a close working relationship between potters, glassmakers, and metalworkers.
Glasses with lead oxide content first appeared in Mesopotamia, the birthplace of the glass industry. The earliest known example is a blue glass fragment from Nippur dated to 1400 BC containing 3.66% PbO, and is mentioned in clay tablets from the reign of Assurbanipal (668–631 BC), and a recipe for lead glaze appears in a Babylonian tablet of 1700 BC. A red sealing-wax cake found in the Burnt Palace at Nimrud, from the early 6th century BC, contains 10% PbO. These low values suggest that lead oxide may not have been consciously added, and was certainly not used as the primary fluxing agent in ancient glasses. Lead glass also occurs in Han-period China (206 BC – 220 AD). Here it was used in cast to imitate jade, both for ritual objects such as big and small figures, as well as jewellery and a limited range of vessels. Since glass occurs at such a late date in China, it is thought that the technology was brought along the Silk Road by glassworkers from the Middle East. The fundamental compositional difference between Western silica-natron glass and the unique Chinese lead glass, however, may indicate a quite different development.
In medieval and early modern Europe lead glass was used as a base in coloured glasses, specifically in mosaic tesserae, enamels, stained-glass painting, and bijouterie, where it was used to imitate precious stones. Several textual sources describing lead glass survive. In his Schedula Diversarum Artium (List Sundry Crafts'), Theophilus describes its use as imitation gemstone, and the title of a lost chapter mentions the use of lead in glass. The 12–13th century Heraclius details the manufacture of lead enamel and its use for window painting in his De Coloribus et artibus Romanorum (Of for Huereds and Crafts Romans'). This refers to lead glass as “Jewish glass”, perhaps indicating its transmission to Europe. A manuscript preserved at San Marco, Venice, describes the use of lead oxide in enamels and includes recipes for calcining lead to form the oxide. Lead glass was ideally suited for enamelling vessels and windows owing to its lower working temperature than the forest glass body.
Antonio Neri devoted his entire book four of his L’Arte Vetraria to lead glass, first published in 1612. In this first systematic treatise on glass, he again refers to the use of lead glass in enamels, glassware, and for the imitation of precious stones. Christopher Merrett translated this into English in 1662 (The Art of Glass), paving the way for the production of English lead crystal glass by George Ravenscroft.
George Ravenscroft (1618–1681) was the first to produce clear lead crystal glassware on an industrial scale. The son of a merchant with close ties to Venice, Ravenscroft had the cultural and financial resources necessary to revolutionise the glass trade, allowing England to overtake Venice as the centre of the glass industry in the eighteenth and nineteenth centuries. With the aid of Venetian glassmakers, especially da Costa, and under the auspices of the Glass Sellers Guild, Ravenscroft sought to find an alternative to Venetian cristallo. His use of flint as the silica source has led to the term flint glass to describe these crystal glasses, despite his later switch to sand. At first, his glasses tended to crizzle, developing a network of small cracks destroying its transparency, which was eventually overcome by replacing some of the potash flux with lead oxide to the melt, up to 30%. Crizzling results from the destruction of the glass network by an excess of alkali, and may be caused by excess humidity as well as inherent defects in glass composition. He was granted a protective patent in 1673, where production and refinement moved from his glasshouse on the Savoy to the seclusion of Henley-on-Thames, and in 1676, having apparently overcome the crizzling problem, was granted the use of a raven’s head seal as a guaranty of quality. In 1681, the year of his death, the patent expired and operations quickly developed amongst several firms, where by 1696 twenty-seven of the eighty-eight glasshouses in England were producing flint glass containing 30–35% PbO, especially at London and Bristol.
At this period, glass was sold by weight, and the typical forms were rather heavy and solid with minimal decoration. Such was its success on the international market, however, that in 1746 the British Government imposed a lucrative tax by weight. Rather than drastically reduce the lead content of their glass, manufacturers responded by creating highly-decorated, smaller, more-delicate forms, often with hollow stems, known to collectors today as Excise glasses. In 1780, the Government granted Ireland free trade in glass without taxation. English labour and capital then shifted to Dublin and Belfast, and new glassworks specialising in cut glass were installed in Cork and Waterford. In 1825, the tax was renewed, and gradually the industry declined until the mid-nineteenth century, when they were finally repealed.
From this period, English lead glass became popular throughout Europe, and was ideally suited to the new taste for wheel-cut glass decoration perfected on the Continent owing to its relatively soft properties. In Holland, local engraving masters such as David Wolff and Frans Greenwood stippled imported English glassware, a style that remained popular through the eighteenth century. Such was its popularity in Holland that the first Continental production of lead-crystal glass began there, probably as the result of imported English workers. Imitating lead-crystal à la façon d’Angleterre presented technical difficulties, as the best results were obtained with covered pots in a coal-fired furnace, a particularly English process requiring specialised cone-furnaces. Towards the end of the eighteenth century, lead-crystal glass was being produced in France, Germany, and Norway. By 1800, Anglo-Irish lead crystal had overtaken lime-potash glasses on the Continent, and traditional glassmaking centres in Bohemia began to focus on colored glasses rather than compete directly against it.
The development of lead glass continued through the twentieth century, when in 1932 scientists at the Corning Glassworks, New York, developed a new lead glass of high optical clarity. This became the focus of Steuben glassworks, a division of Corning, which produced decorative vases, bowls, and glasses in Art Deco style. Lead-crystal continues to be used in industrial and decorative applications.
The fluxing and refractive properties valued for lead glass also make it attractive as a pottery or ceramic glaze. Lead glazes first appear in first century BC to first century AD Roman wares, and occur nearly simultaneously in China. They were very high in lead, 45–60% PbO, with a very low alkali content, less than 2%. From the Roman period, they remained popular through the Byzantine and Islamic periods in the Near East, on pottery vessels and tiles throughout medieval Europe, and up to the present day. In China, similar glazes were used from the twelfth century for colored enamels on stoneware, and on porcelain from the fourteenth century. These could be applied in three different ways. Lead could be added directly to a ceramic body in the form of a lead compound in suspension, either from galena (PbS), red lead (Pb3O4), white lead (2PbCO3·Pb(OH)2), or lead oxide (PbO). The second method involves mixing the lead compound with silica, which is then placed in suspension and applied directly. The third method involves fritting the lead compound with silica, powdering the mixture, and suspending and applying it. The method used on a particular vessel may be deduced by analysing the interaction layer between the glaze and the ceramic body microscopically.
Tin-opacified glazes appear in Iraq in the eighth century AD. Originally containing 1–2% PbO, by the eleventh century high-lead glaze had developed, typically containing 20–40% PbO and 5–12% alkali. These were used throughout Europe and the Near East, especially in Iznik ware, and continue to be used today. Glazes with even-higher lead content occur in Spanish and Italian maiolica, with up to 55% PbO and as low as 3% alkali. Adding lead to the melt allows the formation of tin oxide more readily than in an alkali glaze, which precipitates into crystals in the glaze as it cools, creating its opacity.
The use of lead glaze has several advantages over alkali glazes in addition to their greater optical refractivity. Lead compounds in suspension may be added directly to the ceramic body. Alkali glazes must first be mixed with silica and fritted prior to use, since they are soluble in water, requiring additional work input. A successful glaze must not crawl, or peel away from the pottery surface upon cooling, leaving areas of unglazed ceramic. Lead reduces this risk by reducing the surface tension of the glaze. It must not craze, forming a network of cracks, nor peel. This is caused when the thermal contraction of the glaze and the ceramic body do not match properly. Ideally, the glaze contraction should be 5–15% less than the body contraction, as glazes are stronger under compression than under tension. A high-lead glaze has a linear expansion coefficient of between 5 and 7×10−6/°C, compared to 9 to 10×10−6/°C for alkali glazes. Those of earthenware ceramics vary between 3 and 5×10−6/°C for non-calcareous bodies and 5 to 7×10−6/°C for calcareous clays, or those containing 15–25% CaO. Therefore the thermal contraction of lead glaze matches that of the ceramic more closely than an alkali glaze, rendering it less prone to crazing. A glaze should also have a low enough viscosity to prevent the formation of pinholes as trapped gasses escape during firing, typically between 900–1100 °C, but not so low as to run off. The relatively-low viscosity of lead glaze mitigates this issue. It may also have been cheaper to produce than alkali glazes. Lead glass and glazes have a long and complex history, and continue to play new roles in industry and technology today.
Lead oxide added to the molten glass gives lead crystal a much higher index of refraction than normal glass, and consequently much greater "sparkle" by increasing specular reflection and the range of angles of total internal reflection. Ordinary glass has a refractive index of n = 1.5; the addition of lead produces an index of refraction of up to 1.7. This heightened refractive index also raises the correlating index of dispersion, which measures the degree to which a medium separates light into its component spectra, as in a prism. This increase in refractive index from 1.5 to 1.7 significantly increases the amount of light reflected (by a factor of 1.68 for light reflecting in the normal direction; see Fresnel equations).
In cut glass, which has been hand- or machine-cut with facets, the presence of lead also makes the glass softer and easier to cut. Crystal can consist of up to 35% lead, at which point it has the most sparkle.
Makers of lead crystal objects include
Name Polity Baccarat France Arc International France Royal Leerdam Crystal Netherlands Steuben Glass United States Waterford Crystal Ireland Mikasa Japan NovaScotian Crystal Canada Liuligongfang Taiwan Swarovski Austria Preciosa Czech Republic
It has been proposed that the historic association of gout with the upper classes in Europe and America was, in part, caused by their extensive use of lead crystal decanters to store fortified wines and whisky. Lin et al. have statistical evidence linking gout to lead poisoning.
Items made of lead glass may leach lead into the food and beverages contained. In a study performed at North Carolina State University, the amount of lead migration was measured for Port wine stored in lead crystal decanters. After two days, lead levels were 89 µg/L (micrograms per liter). After four months, lead levels were between 2,000 and 5,000 µg/L. White wine doubled its lead content within an hour of storage and tripled it within four hours. Some brandy stored in lead crystal for over five years had lead levels around 20,000 µg/L. To put this into perspective, the U.S. Environmental Protection Agency's lead standard for drinking water is 15 µg/L = 15 parts per billion. Citrus juices and other acidic drinks leach lead from crystal as effectively as alcoholic beverages. When lead-glass beverage containers are used in the ordinary usual way they do not pose a health risk. Under conditions of repeated use of the decanter, the lead leaching steeply decreases with increasing use. This finding is "consistent with ceramic chemistry theory, which predicts that leaching of Pb from crystal is self-limiting exponentially as a function of increasing distance from the crystal-liquid interface." Lead leaching still occurs, but the quantity that leaches into a glass of wine or other beverage let stand for a few hours is much smaller than the quantity of lead consumed daily in ordinary diet. An ordinary diet contains about 70 µg of lead per day.
- ^ a b c d e f g Newton, Roy G.; Sandra Davison (1989). Conservation of Glass. Butterworth – Heinemann Series in Conservation and Museology. London: Butterworths. ISBN 0-408-10623-9.
- ^ a b c d e Hurst-Vose, Ruth (1980). Glass. Collins Archaeology. London: Collins. ISBN 0002113791.
- ^ a b c d e Tait, Hugh, ed (2004). Five Thousand Years of Glass. University of Pennsylvania Press (orig. British Museum Press). ISBN 978-0-8122-1888-6.
- ^ James F. Shackelford, Robert H. Doremus (2008). Ceramic and Glass Materials: Structure, Properties and Processing. Springer. p. 158. ISBN 0387733612. http://books.google.com/?id=ASIYuNCp81YC&pg=PA158&dq=%22glass+solders%22&cd=3#v=onepage&q=%22glass%20solders%22.
- ^ Fiori, Cesare; Mariangela Vandini (2004). "Chemical Composition of Glass and its Raw Materials". In Marco Beretta. When Glass Matters: Studies in the History of Science and Art from Graeco-Roman Antiquity to Early Modern Era. Florence: Olschki. ISBN 8822253183.
- ^ a b c d Charleston, R.J. (1960). "Lead in Glass". Archaeometry 3 (1): 1–4. doi:10.1111/j.1475-4754.1960.tb00508.x.
- ^ MacLeod, C. (1987). "Accident or Design? George Ravencroft’s Patent and the Invention of Lead-Crystal Glass". Technology and Culture (Society for the History of Technology) 28 (4): 776–803. doi:10.2307/3105182. JSTOR 3105182.
- ^ a b c d e Tite, M.S.; I. Freestone, R. Mason, J. Molera, M. Vendrell-Saz, N. Wood (1998). "Lead Glazes in Antiquity: Methods of Production and Reasons for Use". Archaeometry 40 (2): 241–260. doi:10.1111/j.1475-4754.1998.tb00836.x.
- ^ Emsley, John (2005). Elements of murder. Oxford University Press. ISBN 0192805991. http://books.google.com/?id=qBnfMimUoCYC&printsec=frontcover.
- ^ Lin; Tan, DT; Ho, HH; Yu, CC (2002). "Environmental lead exposure and urate excretion in the general population.". The American journal of medicine 113 (7): 563–8. doi:10.1016/S0002-9343(02)01296-2. PMID 12459402.
- ^ Dixie Farley (Jan–February 1998). "Dangers of Lead Still Linger". FDA Consumer Magazine (U.S. Food and Drug Administration). http://www.fda.gov/FDAC/features/1998/198_lead.html.
- ^ "Lead Crystalware and Your Health". It's Your Health. Health Canada. http://www.hc-sc.gc.ca/hl-vs/iyh-vsv/prod/crystal-cristal-eng.php.
- ^ Angela M. Fraser, Ph.D., Associate Professor/Food Safety Specialist, and Carolyn J. Lackey, Ph.D., R.D., L.D.N., Professor/Food and Nutrition Specialist, North Carolina State University (2004)
- ^ Storing Wine in Crystal Decanters May Pose Lead Hazard. Lawrence K. Altman. New York Times. February 19, 1991
- ^ Graziano, P (1991). "Lead exposure from lead crystal". The Lancet 337 (8734): 141. doi:10.1016/0140-6736(91)90803-W.
- ^ Commonly Asked Questions: Section 1417 of the Safe Drinking Water Act and the NSF Standard
- ^ a b Estimation of lead intake from crystalware under conditions of consumer use. Food Addit Contam. 2000 Mar;17(3):205-18.
- ^ a b Release of lead from crystal decanters under conditions of normal use. Food Chem Toxicol. 1994 Mar;32(3):285-8.
Glass science topics Basics Glass formulation
- Borophosphosilicate glass
- Borosilicate glass
- Ceramic glaze
- Chalcogenide glass
- Cobalt glass
- Cranberry glass
- Crown glass
- Flint glass
- Fluorosilicate glass
- Fused quartz
- Gold ruby glass
- Lead glass
- Milk glass
- Phosphosilicate glass
- Photochromic lens glass
- Silicate glass
- Soda-lime glass
- Sodium hexametaphosphate
- Soluble glass
- Tellurite glass
- Ultra low expansion glass
- Uranium glass
- Vitreous enamel
- Wood's glass
Glass-ceramics Glass preparation Optics Surface modification Diverse topics
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