1.
Bowman, Sheridan. Science and the past. London: British Museum Press; 1991.
2.
Henderson, Julian. Ancient glass: an interdisciplinary exploration. Cambridge: Cambridge University Press; 2013.
3.
Janssens, Koen H. A. Modern methods for analysing archaeological and historical glass. Chichester: Wiley; 2013.
4.
Pollard, A. M., Heron, Carl, Royal Society of Chemistry (Great Britain). Archaeological chemistry. 2nd ed. Cambridge: Royal Society of Chemistry; 2008.
5.
Shortland, Andrew J. Lapis lazuli from the kiln: glass and glassmaking in the late Bronze Age. Leuven: Leuven University Press; 2012.
6.
Tait H. 5000 years of glass. New edition. London: British Museum; 2012.
7.
Tite, M. S., Shortland, Andrew J. Production technology of faience and related early vitreous materials. Oxford: School of Archaeology; 2008.
8.
Freestone I. Looking into glass. Science and the past [Internet]. London: British Museum Press; 1991. p. 37–56. Available from: http://www.jstor.org/stable/10.3138/j.ctt2tv44s.8
9.
Henderson J. The scientific analysis of ancient glass and its archaeological interpretation. Scientific analysis in archaeology and its interpretation [Internet]. Oxford: Oxford University Committee for Archaeology, Institute of Archaeology; 1989. p. 30–62. Available from: https://contentstore.cla.co.uk//secure/link?id=9fd78faf-7736-e711-80c9-005056af4099
10.
Pollard M, Heron C. Chapter 5: The chemistry and corrosion of archaeological glass. Archaeological chemistry [Internet]. 2nd ed. Cambridge: Royal Society of Chemistry; 2008. p. 144–192. Available from: http://UCL.eblib.com/patron/FullRecord.aspx?p=1185179
11.
Anaf W. Study on the formation of heterogeneous structures in leached layers during the corrosion process of glass [Internet]. 2010. Available from: http://ceroart.revues.org/1561
12.
Brill RH. A Note on the Scientist’s Definition of Glass. Journal of Glass Studies [Internet]. 1962;4:127–138. Available from: https://www.jstor.org/stable/24182690
13.
Brill RH. Physical properties of early Chinese glass. In: Brill RH, Martin JH, editors. Scientific research in early Chinese glass : proceedings of the Archaeometry of Glass Sessions of the 1984 International Symposium on Glass, Beijing, September 7, 1984, with supplementary papers. Corning, N.Y.: Corning Museum of Glass; 1991. p. 109–117.
14.
Freestone I. Post-depositional changes in archaeological ceramics and glasses. Handbook of archaeological sciences. Chichester: John Wiley; 2001. p. 615–625.
15.
Ponting M. The scanning electron microscope and the archaeologist. Physics Education [Internet]. 2004;39(2):166–170. Available from: http://iopscience.iop.org/0031-9120/39/2/004/pdf/0031-9120_39_2_004.pdf
16.
Sax M. The introduction of the lapidary engraving wheel in Mesopotamia. Antiquity [Internet]. 2000;74(284):380–387. Available from: http://search.ebscohost.com/login.aspx?direct=true&AuthType=ip,shib&db=asu&AN=505864605&site=ehost-live&scope=site
17.
Schreurs JWH, Brill RH. Iron and sulfur related colours in ancient glasses. Archaeometry. 1984;26(2).
18.
Schreiner M, Melcher M, Uhlir K. Scanning electron microscopy and energy dispersive analysis: applications in the field of cultural heritage. Analytical and Bioanalytical Chemistry. 2007 Feb;387(3):737–747.
19.
Turner WES, Rooksby HP. Study of the Opalising Agents in Ancient Opal Glasses throughout Three Thousand Four Hundred Years. V Internationaler Glaskongress, München, 29 Juni bis 4 Juli 1959. Frankfurt (Main): Deutsche Glastechniche Gesellschaft; p. 17–27.
20.
Weyl, Woldemar A., Society of Glass Technology. Coloured glasses. Sheffield: Society of Glass Technology; 1976.
21.
Nicholson PT. Faience Technology [Internet]. Wendrich W, editor. 2009. Available from: http://escholarship.org/uc/item/9cs9x41z?query=nicholson%20faience#page-2
22.
Nicholson P. Glass Working, Use and Discard [Internet]. 2001. Available from: http://escholarship.org/uc/item/2w17t0cw
23.
Shortland A. Glass Production [Internet]. 2009. Available from: http://escholarship.org/uc/item/4jv3f665?query=shortland%20glass
24.
Tait, Hugh. Five thousand years of glass. Rev. ed. Philadelphia: University of Pennsylvania Press; 2004.
25.
Brill RH. The chemical interpretation of the texts. Glass and glassmaking in ancient Mesopotamia: an edition of the cuneiform texts which contain instructions for glassmakers with a catalogue of surviving objects [Internet]. Corning, N. Y: Corning Museum of Glass; 1970. p. 105–128. Available from: http://d3seu6qyu1a8jw.cloudfront.net/sites/default/files/collections/EE/EECF0FB5-8390-48EA-8B17-0050D4AADB3F.pdf
26.
Degryse P, Boyce A, Erb-Satullo N, Et al. Isotopic discriminants between late Bronze Age glasses from Egypt and the Near East. Archaeometry. 2010;52(3):380–388.
27.
Friedman, Florence D., Borromeo, Georgina, Leveque, Mimi, Cleveland Museum of Art, Rhode Island School of Design, Kimbell Art Museum. Gifts of the Nile: ancient Egyptian faience. London: Thames & Hudson; 1998.
28.
Hatton GD, Shortland AJ, Tite MS. The production technology of Egyptian blue and green frits from second millennium BC Egypt and Mesopotamia. Journal of Archaeological Science. 2008;35(6):1591–1604.
29.
Kaczmarczyk A. The source of cobalt in ancient Egyptian pigments. Proceedings of the 24th International Archaeometry Symposium. Washington, D.C.: Smithsonian Institution Press; 1986. p. 369–376.
30.
Kaczmarczyk, Alexander, Hedges, Robert E. M. Ancient Egyptian faience: an analytical survey of Egyptian faience from predynastic to Roman times. Warminster: Aris & Phillips; 1983.
31.
Lilyquist, Christine, Wypyski, M. T., Brill, Robert H. Studies in early Egyptian glass. New York: Metropolitan Museum of Art; 1993.
32.
Matin M. An Experimental Investigation into the Accidental Invention of Ceramic Glazes. Archaeometry. Oxford: Research Laboratory for Archaeology and the History of Art; 2014 Aug;56(4):591–600.
33.
Moorey, P. R. S. Ancient Mesopotamian materials and industries: the archaeological evidence. Winona Lake, Ind: Eisenbrauns; 1999.
34.
Nicholson, Paul T. Egyptian faience and glass. Princes Risborough, Bucks: Shire; 1993.
35.
Nicholson, Paul T., Gerisch, Rainer, Brook, Elina, Jackson, Caroline M. Brilliant things for Akhenaten: the production of glass, vitreous materials and pottery at Amarna Site O45.1. London: Egypt Exploration Society; 2007.
36.
Nicholson P, Peltenburg E. Egyptian faience. Ancient Egyptian materials and technology [Internet]. Cambridge: Cambridge University Press; 2000. p. 177–193. Available from: https://contentstore.cla.co.uk//secure/link?id=5a348e72-5b36-e711-80c9-005056af4099
37.
Paul T. Nicholson, Caroline M. Jackson and Katharine M. Trott. The Ulu Burun Glass Ingots, Cylindrical Vessels and Egyptian Glass. The Journal of Egyptian Archaeology [Internet]. Egypt Exploration Society; 1997;83:143–153. Available from: http://www.jstor.org/stable/3822462
38.
Pages-Camagna S, Colinart S. The Egyptian green pigment: It’s manufacturing process and links to Egyptian blue. Archaeometry. 2003;45(4):637–658.
39.
Paynter S, Tite MS. The evolution of glazing technologies in the ancient Near East and Egypt. 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 [Internet]. Oxford: Oxbow; 2001. p. 239–254. Available from: http://www.academia.edu/1201164/The_evolution_of_glazing_technologies_in_the_ancient_Near_East_and_Egypt
40.
Peltenburg E. Early faience: recent studies, origins and relationships with glass. Early vitreous materials [Internet]. London: British Museum; 1987. p. 5–29. Available from: https://contentstore.cla.co.uk//secure/link?id=04c05a6c-7336-e711-80c9-005056af4099
41.
Rehren TH. Ramesside glass-colouring crucibles. Archaeometry. 1997;39(2):355–368.
42.
Rehren Th. A review of factors affecting the composition of early Egyptian glasses and faience: alkali and alkali earth oxides. Journal of Archaeological Science. 2008;35(5):1345–1354.
43.
Rehren T. Late Bronze Age Glass Production at Qantir-Piramesses, Egypt. Science. 2005;308(5729):1756–1758.
44.
Riederer J. Egyptian blue. Artists’ pigments: a handbook of their history and characteristics [Internet]. Washington: National Gallery of Art; 1986. p. 23–45. Available from: https://contentstore.cla.co.uk//secure/link?id=ed91deb2-7436-e711-80c9-005056af4099
45.
Shortland AJ. The use and origin of antimonate colorants in early Egyptian glass. In: Archaeometry. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2002 Nov;(4):517–530.
46.
Shortland, Andrew J. Lapis lazuli from the kiln: glass and glassmaking in the late Bronze Age. Leuven: Leuven University Press; 2012.
47.
Shortland AJ, Tite MS, Ewart I. Ancient exploitation and use of cobalt alums from the Western Oases of Egypt. Archaeometry. 2006;(1):153–168.
48.
Shortland A, Rogers N, Eremin K. Trace element discriminants between Egyptian and Mesopotamian Late Bronze Age glasses. In: Journal of Archaeological Sciences. Journal of Archaeological Science. 2007;34(5):781–789.
49.
Smirniou M, Rehren TH. Direct evidence of primary glass production in late Bronze Age Amarna, Egypt. In: Archaeometry. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2011;53(1):58–80.
50.
Stern, E. M., Schlick-Nolte, Birgit. Early glass of the ancient world, 1600 B.C.-A.D. 50: Ernesto Wolf Collection. Ostfildern: Verlag Gerd Hatje; 1994.
51.
Tite MS. Characterisation of early vitreous materials. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 1987;29(1):21–34.
52.
Tite MS, Freestone IC, Bimson M. Egyptian Faience: an investigation of the methods of production. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 1983;25(1):17–27.
53.
Tite MS, Shortland AJ, Paynter S. The beginnings of vitreous materials in the Near East and Egypt. In: Accounts of Chemical Research. Accounts of Chemical Research [Internet]. 2002;35:585–593. Available from: http://pubs.acs.org/doi/pdf/10.1021/ar000204k
54.
M. S. Tite and M. Bimson. Glazed Steatite: An Investigation of the Methods of Glazing Used in Ancient Egypt. World Archaeology [Internet]. Taylor & Francis, Ltd.; 1989;21(1):87–100. Available from: http://www.jstor.org/stable/124486
55.
Tite MS, Manti P, Shortland AJ. A technological study of ancient faience from Egypt. Journal of Archaeological Science. 2007;34(10):1568–1583.
56.
Vandiver P. Appendix A: The manufacture of faience. Ancient Egyptian faience: an analytical survey of Egyptian faience from predynastic to Roman times. Warminster: Aris & Phillips; 1983. p. A1–A139.
57.
Weatherhead PB. A review and proposal of new criteria for production technologies of Egyptian faience. La couleur dans la peinture et l’émaillage de l’Égypte ancienne: actes de la table ronde, Ravello, 20-22 mars 1997. Bari: Edipuglia; 1989. p. 202–239.
58.
Weatherhead F, Buckley A. Artists’ pigments from Amarna. Amarna reports [Internet]. London: Egypt Exploration Society; 1984. p. 202–239. Available from: https://contentstore.cla.co.uk//secure/link?id=14eb3138-7236-e711-80c9-005056af4099
59.
Wulff HE, Wulff HS, Koch L. Egyptian Faience: A Possible Survival in Iran. Archaeology [Internet]. Archaeological Institute of America; 21(2):98–107. Available from: http://www.jstor.org/stable/41667813
60.
Shortland A, Schachner L, Freestone I, Tite M. Natron as a flux in the early vitreous materials industry: sources, beginnings and reasons for decline. Journal of Archaeological Science. 2006;33(4):521–530.
61.
E. Marianne Stern. Roman Glassblowing in a Cultural Context. American Journal of Archaeology [Internet]. Archaeological Institute of America; 1999;103(3):441–484. Available from: http://www.jstor.org/stable/506970
62.
Tatton-Brown V. Hellenistic and non-blown Roman glass and The Roman Empire. Five thousand years of glass. Rev. ed. Philadelphia: University of Pennsylvania Press; 1991. p. 46–97.
63.
Foster, H.E. ‘A whiter shade of pale’? Chemical and experimental investigation of opaque white Roman glass gaming counters. Glass Technology - European Journal of Glass Science and Technology Part A. Society of Glass Technology; 46(5):327–333.
64.
Freestone I. Laboratory studies of the Portland Vase. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 1990;32:103–107. Available from: http://www.jstor.org/stable/24188034
65.
Grose DF. Innovation and change in ancient technologies. High technology ceramics: past, present, and future : the nature of innovation and change in ceramic technology. Westerville, OH: American Ceramic Society; 1986. p. 65–79.
66.
Grose, David F., Toledo Museum of Art. Early ancient glass: core-formed, rod-formed, and cast vessels and objects from the late Bronze Age to the early Roman Empire, 1600 B.C. to A.D. 50. 1st ed. New York: Hudson Hills Press in association with the Toledo Museum of Art; 1989.
67.
Henderson J. Chemical characterisation of Roman glass vessels, enamels and tesserae. Materials issues in art and archaeology II: symposium held April 17-21, 1990, San Francisco, California, USA [Internet]. Pittsburgh, Pa: Materials Research Society; 1991. p. 601–607. Available from: https://contentstore.cla.co.uk//secure/link?id=69ce3854-7d36-e711-80c9-005056af4099
68.
Israeli Y. The invention of blowing. Roman glass: two centuries of art and invention. London: Society of Antiquaries of London; 1991. p. 46–55.
69.
Israeli Y, Katsnelson N. Refuse of a glass workshop of the second Temple Period from area J. Jewish Quarter excavations in the Old City of Jerusalem: conducted by Nahman Avigad, 1969-1982. Jerusalem: Israel Exploration Society; 2006. p. 411–460.
70.
Liardet F. Learning by hand: artefact consistency and craft tradition. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp. Antwerp: University Press Antwerp; 2009. p. 184–188.
71.
Jackson CM. Making colourless glass in the Roman period. Archaeometry. 2005;47(4):763–780.
72.
Jackson CM, Hunter JR, Warren SE, Cool HEM. The analysis of blue-green glass and glassy waste from two Romano-British glass-working sites. Archaeometry ’90. Basel: Birkhäuser Verlag; 1991. p. 295–305.
73.
Mass JL, Stone RE, Wypyski MT. The mineralogical and metallurgical origins of Roman opaque coloured glasses. The prehistory & history of glassmaking technology. Westerville, OH: American Ceramic Society; 1998. p. 121–144.
74.
Price J. Glass-working and Glassworkers in cities and towns. Roman working lives and urban living [Internet]. Oxford: Oxbow Books; 2005. p. 167–190. Available from: http://dro.dur.ac.uk/3823/1/3823.pdf
75.
Price, J., Cottam, Sally. Romano-British glass vessels: a handbook. York: Council for British Archaeology; 1998.
76.
Reade W, Freestone IC, Bourke S. Innovation or continuity? Early first millennium bce glass in the Near East: the cobalt blue glasses from Assyrian Nimrud. Annales du 16e Congrès de l’Association internationale pour l’histoire du verre, London, 2003 [Internet]. Nottingham: AIHV; 2009. p. 23–27. Available from: https://www.academia.edu/4590703/Innovation_or_continuity_Early_first_millennium_BCE_glass_in_the_Near_East_The_cobalt_blue_glasses_from_Assyrian_Nimrud._with_W_Reade_St_J_Simpson_
77.
Reade W, Freestone IC, Bourke S. Innovation and continuity in Bronze Age and Iron Age glass from Pella in Jordan. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp [Internet]. Antwerp: University Press Antwerp; 2009. p. 47–54. Available from: https://aihv.org/publications/annales-of-17th-congress-of-the-aihv/
78.
E. V. Sayre and R. W. Smith. Compositional Categories of Ancient Glass. Science [Internet]. American Association for the Advancement of Science; 1961;133(3467):1824–1826. Available from: http://www.jstor.org/stable/1707503
79.
Sarye EV, Smith RW. Some materials of glass manufacturing in antiquity. Archeological chemistry: a symposium. Philadelphia: University of Pennsylvania Press; 1967. p. 279–311.
80.
Sayre EV. The intentional use of antimony and manganese in ancient glasses. Advances in glass technology: additional papers from the Sixth International Congress on Glass, held July 8-14, 1962, at Washington, DC, sponsored by the International Commission of Glass, with the American Ceramic Society as host. Teaching collection INST ARCH 3160: Plenum Press; 1963. p. 263–282.
81.
Schlick-Nolte B, Werthmann R. Glass Vessels from the burial of Nesikhons. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2003;45:11–34. Available from: http://www.jstor.org/stable/24191024
82.
Stern, E. M., Schlick-Nolte, Birgit. Early glass of the ancient world, 1600 B.C.-A.D. 50: Ernesto Wolf Collection. Ostfildern: Verlag Gerd Hatje; 1994.
83.
Freestone I, Gorin-Rosen Y, Hughes M. Primary glass from Israel and the production of glass in Late antiquity and the Early Islamic period. La route du verre: ateliers primaires et secondaires du second millénaire av J-C au Moyen Âge [Internet]. Lyon: Maison de l’Orient Méditerranéen; 2000. p. 65–83. Available from: http://www.persee.fr/issue/mom_1274-6525_2000_act_33_1
84.
Freestone IC, Ponting M, Hughes MJ. The origins of Byzantine glass from Maroni Petrera, Cyprus. In: Archaeometry. Archaeometry. 2002;44(2):257–272.
85.
Baxter MJ, Cool HEM, Jackson CM. Further studies in the compositional variability of colourless Romano-British vessel glass. Archaeometry. 2005;47(1):47–68.
86.
Brems D, Degryse P, Hasendoncks F, Gimeno D, Silvestri A, Vassilieva E, Luypaers S, Honings J. Western Mediterranean sand deposits as a raw material for Roman glass production. Journal of Archaeological Science. 2012;39(9):2897–2907.
87.
Brill RH. Scientific investigations of the Jalame glass. Excavations at Jalame: site of a glass factory in late Roman Palestine : excavations conducted by a joint expedition of the University of Missouri and the Corning Museum of Glass. Columbia: University of Missouri Press; 1988. p. 257–294.
88.
Degryse P, Schneider J. Pliny the Elder and Sr–Nd isotopes: tracing the provenance of raw materials for Roman glass production. Journal of Archaeological Science. 2008;35(7):1993–2000.
89.
Degryse P, Schneider J, Lauwers V. Neodymium and strontium isotopes in the provenance determination of primary natron glass production. Isotopes in vitreous materials [Internet]. Leuven, Belgium: Leuven University Press; 2009. Available from: http://www.academia.edu/1971182/Neodymium_and_strontium_isotopes_in_the_provenance_determination_of_primary_natron_glass_production
90.
Foster HE, Jackson CM. The composition of ‘naturally coloured’ late Roman vessel glass from Britain and the implications for models of glass production and supply. Journal of Archaeological Science. 2009;36(2):189–204.
91.
Freestone I. The provenance of ancient glass through compositional analysis. Materials issues in art and archaeology VII: symposium held November 30-December 3, 2004, Boston, Massachusetts, USA [Internet]. Warrendale, Pa: Materials Research Society; 2005. Available from: http://www.academia.edu/4569333/The_provenance_of_ancient_glass_through_compositional_analysis
92.
Freestone I. Glass production in Late Antiquity and the Early Islamic period: a geochemical perspective. Geomaterials in cultural heritage [Internet]. London: The Geological Society; 2006. p. 201–216. Available from: http://sp.lyellcollection.org/content/257/1/201.full.pdf
93.
Freestone I. Pliny on Roman glassmaking. Archaeology, history and science: integrating approaches to ancient materials [Internet]. Walnut Creek, CA: Left Coast Press; 2008. p. 77–100. Available from: http://www.ucl.eblib.com/patron/FullRecord.aspx?p=677776
94.
Freestone IC, Leslie KA, Thirlwall M, Gorin-Rosen Y. Strontium Isotopes in the Investigation of Early Glass Production: Byzantine and Early Islamic Glass from the Near East. Archaeometry. 2003;45(1):19–32.
95.
Freestone I, Price J, Cartwright C. The batch: its recognition and significance. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp [Internet]. Antwerp: University Press Antwerp; 2009. p. 130–135. Available from: https://www.academia.edu/4590808/The_batch_its_recognition_and_significance_with_J_Price_and_C_Cartwright_
96.
Freestone IC, Wolf S, Thirlwall M. The production of HIMT glass: elemental and isotopic evidence. Annales du 16e Congrès de l’Association internationale pour l’histoire du verre, London, 2003 [Internet]. Nottingham: AIHV; 2005. p. 153–157. Available from: http://www.academia.edu/4590712/The_production_of_HIMT_glass_with_S_Wolf_M_Thirlwall_
97.
Freestone IC, Wolf S, Thirlwall M. Isotopic composition of glass from the Levant and South-eastern Mediterranean region. Isotopes in vitreous materials. Leuven, Belgium: Leuven University Press; 2009. p. 31–52.
98.
Ganio M. Roman glass across the Empire: an elemental and isotopic characterization. Journal of Analytical Atomic Spectrometry [Internet]. 2012;27(5):743–753. Available from: http://pubs.rsc.org.libproxy.ucl.ac.uk/en/content/articlepdf/2012/ja/c2ja10355a
99.
Gorin-Rosen Y. The ancient glass industry in Israel: summary of finds and new discoveries. La route du verre: ateliers primaires et secondaires du second millénaire av J-C au Moyen Âge [Internet]. Lyon: Maison de l’Orient Méditerranéen; 2000. p. 49–63. Available from: http://www.persee.fr/issue/mom_1274-6525_2000_act_33_1
100.
Kock, Jan, Sode, Torben. Glass, glass beads and glassmakers in Northern India. Vanlose, Denmark: THOT;
101.
Nenna MD, Picon M, Thirion-Merle V, Vichi M. Ateliers primaires du Wadi Natrun: novelles decouvertes. Annales du 16e Congrès de l’Association internationale pour l’histoire du verre, London, 2003 [Internet]. Nottingham: AIHV; 2005. p. 59–63. Available from: http://www.aihv.org/en/pdf/16-14.pdf
102.
Nenna MD, Picon M, Vichy M. Ateliers primaire et secondaires en Egypt a l’epoque greco-romaine. La route du verre: ateliers primaires et secondaires du second millénaire av J-C au Moyen Âge [Internet]. Lyon: Maison de l’Orient Méditerranéen; 2000. p. 97–112. Available from: http://www.persee.fr/web/revues/home/prescript/issue/mom_1274-6525_2000_act_33_1
103.
Price J, Freestone IC, Cartwright C. ‘All in a day’s work?’. The colourless cylindrical glass cups found at Stonea revisited. Image, craft and the classical world: essays in honour of Donald Bailey and Catherine Johns [Internet]. Montagnac: Éditions Monique Mergoil; 2005. p. 163–169. Available from: http://www.academia.edu/4590761/All_in_a_days_work_The_colourless_cylindrical_glass_cups_found_at_Stonea_revisited_with_J_Price_C_Cartwright_
104.
Sode T, Kock J. Traditional raw glass production in Northern India: the final stage of an ancient technology. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2001;43:155–169. Available from: http://www.jstor.org/stable/24190905
105.
Wedepohl KH, Baumann A. The Use of Marine Molluskan Shells for Roman Glass and Local Raw Glass Production in the Eifel Area (Western Germany). Naturwissenschaften. 2000;87(3):129–132.
106.
Freestone I, Gorin-Rosen Y. The great glass slab at Bet Shearim, Israel: an early Islamic glassmaking experiment? Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 1999;41:105–116. Available from: http://www.jstor.org/stable/24190848
107.
Pinder-Wilson R. The Islamic lands and China. Five thousand years of glass [Internet]. Rev. ed. Philadelphia: University of Pennsylvania Press; 2004. p. 112–143. Available from: https://contentstore.cla.co.uk//secure/link?id=f7e43878-6e36-e711-80c9-005056af4099
108.
Shortland A, Schachner L, Freestone I, Tite M. Natron as a flux in the early vitreous materials industry: sources, beginnings and reasons for decline. In: Journal Archaeological Science. Journal of Archaeological Science. 2006;33(4):521–530.
109.
Arletti R, Fiori C, Vandini M. A study of glass tesserae from mosaics in the monesteries of Daphni and Hosios Loukas (Greece). Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2010;52(5):796–815.
110.
Barber DJ, Freestone IC. An investigation of the origin of the colour of the Lycurgus Cup by analytical transmission electron microscopy. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 1990;32(1):33–45.
111.
Freestone IC, Bimson M, Buckton D. Compositional categories of Byzantine glass tesserae. Annales du 11e Congrès de l’Association internationale pour l’histoire du verre: Bâle, 29 août, 3 septembre 1988 [Internet]. Amsterdam: The Association; 1990. p. 271–280. Available from: http://www.academia.edu/4568952/Compositional_Categories_of_Byzantine_glass_tesserae_with_M_Bimson_and_D_Buckton_
112.
Freestone I, Meeks N, Sax M, Higgitt C. The Lycurgus Cup — A Roman nanotechnology. Gold Bulletin. 2007;40(4):270–277.
113.
Gratuze B, Barrandon JN. Islamic glass weights and stamps: analysis using nuclear techniques. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 1990;32(2):155–162.
114.
Greiff S, Schuster J. Technological study of enamelling on Roman glass: The nature of opacifying, decolourizing and fining agents used with the glass beakers from Lübsow (Lubieszewo, Poland). Journal of Cultural Heritage. 2008;9:e27–e32.
115.
Gudenrath W. Enameled glass vessels, 1425 BCE - 1800: The decorating process. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2006;48:23–70. Available from: http://www.jstor.org/stable/24191146
116.
Henderson J. Investigations into marvered glass 2. Islamic art in the Ashmolean Museum [Internet]. Oxford: Oxford University Press for the Board of Faculty of Oriental Studies, University of Oxford; 1995. p. 31–50. Available from: https://contentstore.cla.co.uk//secure/link?id=01f15fb5-4c36-e711-80c9-005056af4099
117.
Henderson J. An investigation of early glass production at Raqqa, Syria. Materials issues in art and archaeology IV: symposium held May 16-21, 1994, Cancun, Mexico. Pittsburgh, Pa: Materials Research Society; 1995. p. 433–443.
118.
Henderson, Julian. Archaeological and Scientific Evidence for the Production of Early Islamic Glass in al-Raqqa, Syria. Levant. Maney Publishing; 1999;31(1):225–240.
119.
Henderson J. Tradition and Experiment in First Millennium A.D. Glass ProductionThe Emergence of Early Islamic Glass Technology in Late Antiquity. Accounts of Chemical Research. 2002;35(8):594–602.
120.
Mirti P, Pace M, Malandrino M, Ponzi MN. Sasanian glass from Veh Ardašīr: new evidences by ICP-MS analysis. Journal of Archaeological Science. 2009;36(4):1061–1069.
121.
Sayre EV, Smith RW. Analytical studies of ancient Egyptian glass. Recent advances in science and technology of materials: [proceedings] [Internet]. New York: Plenum Press; 1974. p. 47–70. Available from: http://www.osti.gov/scitech/servlets/purl/4328677
122.
Schibille N, Marii F, Rehren Th. Charaterization and provenance of late antique window glass from the Petra church in Jordan. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2008;50(4):627–642.
123.
Silvestri A, Tonietto S, Molin G. The palaeo-Christian glass mosaic of St. Prosdocimus (Padova, Italy): archaeometric characterisation of ‘gold’ tesserae. Journal of Archaeological Science. 2011;38(12):3402–3414.
124.
Smith RW. Archaeological evaluation of analyses of ancient glass. Advances in glass technology: additional papers from the Sixth International Congress on Glass, held July 8-14, 1962, at Washington, DC, sponsored by the International Commission of Glass, with the American Ceramic Society as host. New York: Plenum Press; 1963. p. 283–290.
125.
Verità M, Santopadre P. Analysis of Gold-Coloured ruby glass tesserae in roman church mosaics of the fourth to 12th Centuries. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2010;52:11–24. Available from: http://www.jstor.org/stable/24191199
126.
Hilgner, Alexandra, Zorn, Bettina, Römisch-Germanisches Zentralmuseum Mainz, Shanxi Sheng kao gu yan jiu suo (Xi’an Shi, China). Glass along the silk road from 200 BC to AD 1000: international conference within the scope of the ‘Sino-German Project on Cultural Heritage Preservation’ of the RGZM and the Shaanxi Provincial Institute of Archaeology, December 11th-12th 2008. Mainz: Verlag des Römisch-Germanischen Zentralmuseums; 2010.
127.
Freestone, Ian, Gaimster, David R. M. Pottery in the making: world ceramic traditions. London: British Museum Press; 1997.
128.
Tite MS, Freestone I, Mason R, Et al. Lead glazes in antiquity - methods of production and reasons for use. In: Archaeometry. Archaeometry. 1998;40(2):241–260.
129.
Bernsted, Anne-Marie Keblow. Early Islamic pottery: materials and techniques. London: Archetype; 2003.
130.
Mason, Robert B. Shine like the sun: lustre-painted and associated pottery from the medieval Middle East. Costa Mesa, Calif: Mazda Publishers in association with Royal Ontario Museum; 2004.
131.
Mason RB, Tite MS. The beginnings of Islamic stonepaste technology. Archaeometry. 1994;36(1):77–91.
132.
Mason RB, Tite MS. The beginnings of tin-opacification of pottery glazes. Archaeometry. 1997;39(1):41–58.
133.
Paynter S. Links between glazes and glass in mid-2nd millennium BC Mesopotamia and Egypt. In: Shortland AJ, Freestone I, Rehren T, editors. From mine to microscope: advances in the study of ancient technology [Internet]. Oxford, UK: Oxbow Books; 2009. p. 93–108. Available from: http://www.ucl.eblib.com/patron/FullRecord.aspx?p=1696495
134.
Walton MS, Tite MS. Production technology of Roman lead-glazed pottery and its continuance into late antiquity. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2010;52(5):733–759.
135.
Lankton JW, Dussubieux L. Early glass in Asian Maritime Trade: a review and an interpretation of compositional analyses. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2006;48:121–144. Available from: http://www.jstor.org/stable/24191148
136.
Wood N. The influence of glass technology on Chinese ceramics. [Internet]. International Ceramics Fair and Seminar, London.; 2001. Available from: http://www.haughton.com/system/files/articles/2010/01/27/86/icf_s_2001_4th.pdf
137.
Vandiver PB. Ancient Glazes. Scientific American [Internet]. 1990;262:106–113. Available from: http://www.nature.com.libproxy.ucl.ac.uk/scientificamerican/journal/v262/n4/pdf/scientificamerican0490-106.pdf
138.
An J. The early glass of China. Scientific research in early Chinese glass: proceedings of the Archaeometry of Glass Sessions of the 1984 International Symposium on Glass, Beijing, September 7, 1984, with supplementary papers. Corning, N.Y: Corning Museum of Glass; 1991. p. 1–19.
139.
Braghin, Cecilia. Chinese glass: archaeological studies on the uses and social context of glass artefacts from the Warring States to the Northern Song period; (fifth century B.C. to twelfth century A.D.). Firenze: Leo S. Olschki; 2002.
140.
Martin, John H., Brill, Robert H., Archaeometry of Glass Sessions, International Commission on Glass, International Symposium on Glass. Scientific research in early Chinese glass: proceedings of the Archaeometry of Glass Sessions of the 1984 International Symposium on Glass, Beijing, September 7, 1984, with supplementary papers. Corning, N.Y: Corning Museum of Glass; 1991.
141.
Brill RH, Tong SSC, Dohrenwend D. Chemical analyses of some early Chinese glasses. Scientific research in early Chinese glass: proceedings of the Archaeometry of Glass Sessions of the 1984 International Symposium on Glass, Beijing, September 7, 1984, with supplementary papers [Internet]. Corning, N.Y: Corning Museum of Glass; 1991. p. 31–58. Available from: http://www.cmog.org/sites/default/files/collections/A4/A48B894F-67C7-4DC0-946D-7E5EB13F7FB8.pdf
142.
Cheng Z, Zhou C. A glass garment from a Western Han tomb in Jiangsu province. Scientific research in early Chinese glass: proceedings of the Archaeometry of Glass Sessions of the 1984 International Symposium on Glass, Beijing, September 7, 1984, with supplementary papers. Corning, N.Y: Corning Museum of Glass; 1991. p. 21–26.
143.
Curtis EB. European contributions to the Chinese Glass of the Early Qing Period. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 1993;35:91–101. Available from: http://www.jstor.org/stable/24191062
144.
Dussubieux L, Robertshaw P, Glascock MD. LA-ICP-MS analysis of African glass beads: Laboratory inter-comparison with an emphasis on the impact of corrosion on data interpretation. International Journal of Mass Spectrometry. 2009;284(1–3):152–161.
145.
Dussubieux L, Gratuze B, Blet-Lemarquand M. Mineral soda alumina glass: occurence and meaning. Journal of Archaeological Science. 2010;37(7):1646–1655.
146.
Dussubieux L, Kusimba CM, Gogte V, Et al. The trading of ancient glass beads: new analytical data from South Asian and East African soda-alumina glass beads. In: Archaeometry. Archaeometry. 2008;50(5):797–821.
147.
Elisabeth West FitzHugh and Lynda A. Zycherman. An Early Man-Made Blue Pigment from China: Barium Copper Silicate. Studies in Conservation [Internet]. Maney Publishing; 1983;28(1):15–23. Available from: http://www.jstor.org/stable/1506102
148.
Elisabeth West FitzHugh and Lynda A. Zycherman. A Purple Barium Copper Silicate Pigment from Early China. Studies in Conservation [Internet]. Maney Publishing; 1992;37(3):145–154. Available from: http://www.jstor.org/stable/1506342
149.
Glover I, Henderson J. Early glass in South and South east Asia and China. South East Asia & China: art, interaction & commerce. London: University of London, Percival David Foundation of Chinese Art, School of Oriental and African Studies; 1995. p. 141–169.
150.
Kock J, Sode T. Medieval glass mirrors in Southern Scandinavia and their technique, as still practiced in India. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2002;44:79–94. Available from: http://www.jstor.org/stable/24190873
151.
Kowzuka T, Yamasaki K. Scientific study on the glass beads found in the Yayoi period of Japan. Scientific research in the field of Asian art: proceedings of the first Forbes Symposium at the Freer Gallery of Art. London: Archetype; 2003. p. 183–191.
152.
Lee IS. Chemical analyses of some ancient glasses from Korea. Annales du 12e Congrès de l’association internationale pour l’histoire du verre: Vienne-Wien, 26-31 août 1991. Amsterdam: The Association; 1993. p. 163–175.
153.
Pinder-Wilson R. The Islamic Lands and China. Five thousand years of glass [Internet]. Rev. ed. Philadelphia: University of Pennsylvania Press; 1991. p. 112–143. Available from: https://contentstore.cla.co.uk/secure/link?id=f7e43878-6e36-e711-80c9-005056af4099
154.
Wiedemann HG, Bayer G, Reller A. Egyptian blue and Chinese blue. Production technologies and applications of two historically important blue pigments. La couleur dans la peinture et l’émaillage de l’Égypte ancienne: actes de la table ronde, Ravello, 20-22 mars 1997. Bari: Edipuglia; 1998. p. 195–203.
155.
Wood M. A glass bead sequence for Southern Africa from the 8th to the 16th Century AD. Journal of African archaeology. Frankfurt am Main: Africa Magna Verlag; 2011;9(1):67–84.
156.
Wood N. New discoveries in Chinese ceramics. [Internet]. International Ceramics Fair and seminar, London; 1997. Available from: http://www.haughton.com/system/files/articles/2010/01/27/102/icf_s_1997_4th.pdf
157.
Wood, Nigel. Chinese glazes: their origins, chemistry, and re-creation. London: A & C Black; 1999.
158.
Yin M, Rehren T, Zheng J. The earliest high-fired glazed ceramics in China: the composition of the proto-porcelain from Zhejiang during the Shang and Zhou periods (c. 1700–221 BC). Journal of Archaeological Science. 2011;38(9):2352–2365.
159.
Freestone I. Theophilus and the composition of Medieval glass. Materials issues in art and archaeology III : symposium held April 27-May 1, 1992, San Francisco, California, USA [Internet]. Pittsburgh, Pa: Materials Research Society; 1992. p. 739–745. Available from: https://contentstore.cla.co.uk//secure/link?id=1a8e175c-7d36-e711-80c9-005056af4099
160.
Freestone I, Hughes MJ. Origins of the Jarrow glass. Wearmouth and Jarrow monastic sites [Internet]. Swindon: English Heritage; 2006. p. 147–155. Available from: https://www.academia.edu/4581603/Origins_of_the_Jarrow_Glass_with_M_Hughes_
161.
Wolf S, Kessler CM, Stern WB, Gerber Y. Early medieval glass from Sion, Sous-le-Scex (Valais, Switzerland) – Roman glass-making traditions or innovative craftsmanship? Archaeometry. 2005;47(2):361–380.
162.
Wolf S, Kessler CM, Stern WB, Gerber Y. The composition and manufature of early Medieval coloured window glass from Sion (Valais, Switzerland) - A Roman glass-making tradition or innovative craftmanship? Archaeometry. 2005;47(2):361–380.
163.
Henderson J. Aspects of early medieval glass production in Britain. Annales du 12e Congrès de l’association internationale pour l’histoire du verre: Vienne-Wien, 26-31 août 1991. Amsterdam: The Association; 1993. p. 247–259.
164.
Henderson J. Technological characteristics of Roman enamels. Jewellery studies: volume 5: 1991 [Internet]. Gloucester: Society of Jewellery Historians; 1991;65–77. Available from: https://contentstore.cla.co.uk//secure/link?id=72c02a04-4b36-e711-80c9-005056af4099
165.
Kreuger I. Glass-mirrors in medieval times. Annales du 12e Congrès de l’association internationale pour l’histoire du verre: Vienne-Wien, 26-31 août 1991. Amsterdam: The Association; 1993. p. 319–332.
166.
Jackson CM. From Roman to early medieval glasses. Many happy returns or a new birth? Annales du 13e Congrès de l’association internationale pour l’histoire du verre: Pays Bas, 28 août-1 septembre 1995. Lochem, The Netherlands: The Association; 1996. p. 289–301.
167.
Mirti P, Lepora A, Sagui L. Scientific analysis of Seventh-Century glass fragments from the Crypta Balbi in Rome. Archaeometry. 2000;42(2):359–374.
168.
Mirti P, Davit P, Gulmini M, Sagui L. Glass Fragments from the Crypta Balbi in Rome: the Composition of Eighth-Century Fragments. Archaeometry. 2001;43(4):491–502.
169.
Rohrs S, Biron I, Stege H. About Limoges painted enamels - chronological evolution of the glass chemical composition. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp. Antwerp: University Press Antwerp; 2009. p. 500–509.
170.
Verità M, Santopadre P. Analysis of Gold-Coloured ruby glass tesserae in roman church mosaics of the fourth to 12th Centuries. Journal of glass studies [Internet]. [Corning, N.Y.]: Corning Museum of Glass; 2010;52:11–24. Available from: http://www.jstor.org/stable/24191199
171.
Verità M, Zecchini S. Thousand years of Venetian glass: the evolution of chemical composition from the origin to the 18th Century. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp. Antwerp: University Press Antwerp; 2009. p. 602–613.
172.
Wolf S, Kessler C. Early medieval window glass from Switzerland and a brief history of glass production in Europe in the first millennium AD. Glass along the silk road from 200 BC to AD 1000: international conference within the scope of the ‘Sino-German Project on Cultural Heritage Preservation’ of the RGZM and the Shaanxi Provincial Institute of Archaeology, December 11th-12th 2008. Mainz: Verlag des Römisch-Germanischen Zentralmuseums; 2010. p. 29–37.
173.
Bimson M, Freestone IC. ‘Rouge Clair’ and other late 14th Century enamels on the Royal Gold cup of the Kings of France and England. Annales du 9e Congrès international d’étude historique du verre: Nancy (France), 22-28 mai 1983. Liège: Centre de Publications de l’A.I.H.V; 1985. p. 209–222.
174.
Biron I, Beauchoux S bastien. Ion beam analysis of Mosan enamels. Measurement Science and Technology. 2003;14(9):1564–1578.
175.
Biron I, Dandridge P, Wypski MT. Techniques and materials in Limoges enamels. Enamels of Limoges, 1100-1350. New York: Metropolitan Museum of Art; 1996. p. 48–62.
176.
Brun N, Pernot M. The opaque red glass of Celtic enamels from continental Europe. Archaeometry. 1992;34(2):235–252.
177.
Craddock, P. T. Scientific investigation of copies, fakes and forgeries. Oxford: Butterworth-Heinemann; 2009.
178.
Dandrige P, Wypuski MT. Preliminary technical study on Medieval Limoges enamels. Materials issues in art and archaeology III: symposium held April 27-May 1, 1992, San Francisco, California, USA. Pittsburgh, Pa: Materials Research Society; 1992. p. 817–826.
179.
Freestone IC. Compositions and origins of glasses from Romanesque champleve enamels. Catalogue of medieval enamels in the British Museum [Internet]. London: Published for the Trustees of the British Museum by British Museum Press; 1993. p. 37–45. Available from: https://contentstore.cla.co.uk//secure/link?id=0f61d52c-6336-e711-80c9-005056af4099
180.
Henderson J. Technological Characteristics of Roman Enamels. Jewellery Studies [Internet]. 1991;5:65–76. Available from: https://contentstore.cla.co.uk/secure/link?id=72c02a04-4b36-e711-80c9-005056af4099
181.
Joyner L, Freestone I, Robinson J. Crowning glory: the identification of gems on the head reliquary of St Eustace from the Basle Cathedral Treasury. Gem-A | The Gemmological Association of Great Britain. 2006;30:169–182.
182.
Monique Perez y Jorba, Monique Rommeluere and Léo Mazerolles. Etude de la deterioration d’une plaque d’email peint de Limoges. Studies in Conservation [Internet]. Maney Publishing; 1993;38(3):206–212. Available from: http://www.jstor.org.libproxy.ucl.ac.uk/stable/1506381
183.
Rika Smith, Janice H. Carlson and Richard M. Newman. An Investigation into the Deterioration of Painted Limoges Enamel Plaques c. 1470-1530. Studies in Conservation [Internet]. Maney Publishing; 1987;32(3):102–113. Available from: http://www.jstor.org/stable/1506214
184.
Stapleton CP, Freestone IC, Bowman SGE. Composition and Origin of Early Mediaeval Opaque Red Enamel from Britain and Ireland. Journal of Archaeological Science. 1999;26(8):913–921.
185.
Tait H, Freestone I. Painted enamel ‘patches’: a nineteenth century virtuoso restorer’s technique. New research on Limoges enamels [Internet]. 2004. p. 117–122. Available from: https://www.academia.edu/24017369/Painted_enamel_patches_a_nineteenth_century_virtuoso_restorer_s_technique_Hugh_Tait_and_Ian_Freestone_2004_
186.
Verita M, Cagnini A, Galeotti M, Cavalca N, Porcinai S. Compositional Analysis of 14th-15th Century Enamels from the Altar of San Giovanni in Florence: an Integrated Study by Portable X-Ray Fluorescence and Electron Probe Microanalysis. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art; 2013;55(6):1048–1066.
187.
Wypyski MT. Renaissance Enameled Jewelry and 19th century Renaissance Revival: Characterization of Enamel Compositions. MRS Proceedings. 2002;712.
188.
Berrera J, Velde B. A study of French medieval glass composition. Journal of Glass Studies [Internet]. Corning, N.Y.: Corning Museum of Glass; 1989;31:48–54. Available from: http://www.jstor.org/stable/24190095
189.
Cable M. The operation of wood-fired glass-melting furnaces. The prehistory & history of glassmaking technology / editor Patrick McCray. 1998. p. 315–330.
190.
Cox GA, Gillies KJS. The x-ray fluorescence analysis of Medieval durable blue soda glass from York Minster. Archaeometry. 1986;28(1):57–68.
191.
Cox GA, Heavens OS, Newton RG, Pollard AM. A study of the weathering behaviour of medieval glass from York Minster. Journal of glass studies [Internet]. 1979;21:54–75. Available from: http://www.jstor.org/stable/24190036
192.
Freestone IC, Bimson M. Early Venetian enamelling on glass: technology and origins. Materials issues in art and archaeology IV : Cancun, Mexico, May 16-20, 1994 : abstracts. 1995. p. 54–75.
193.
Freestone I, Bimson M. Multi-disciplinary Investigation of the Windows of John Thornton, focusing on the Great East Window of York Minster. The art of collaboration: stained-glass conservation in the Twenty-First Century [Internet]. 2010. p. 151–158. Available from: http://discovery.ucl.ac.uk/1397658/
194.
Jackson, C.M. Medieval and post-medieval glass technology: seasonal changes in the composition of bracken ashes from different habitats through a growing season. Glass Technology - European Journal of Glass Science and Technology Part A. Society of Glass Technology; 2008;49(5):240–245.
195.
Jackson CM, Smedley JW. Theophilus and the use of beech ash as a glassmaking alkali. Archaeology, history and science: integrating approaches to ancient materials [Internet]. Walnut Creek, CA: Left Coast Press; 2008. p. 117–130. Available from: http://www.ucl.eblib.com/patron/FullRecord.aspx?p=677776
196.
Jacoby D. Raw materials for the glass industries of Venice and the Terraferma, about 1370 - about 1460. Journal of glass studies [Internet]. 1993;35:65–90. Available from: http://www.jstor.org/stable/24191061
197.
Marks R. Stained glass in England during the Middle Ages. London: Routledge; 1993.
198.
Stern WB, Gerber Y. Potassium-Calcium Glass: New Data and Experiments. Archaeometry. 2004;46(1):137–156.
199.
Smedley J.W. Medieval and post-medieval glass technology: a review of bracken in glassmaking. Glass Technology - European Journal of Glass Science and Technology Part A. Society of Glass Technology; 2002;43(6):221–224.
200.
Smedley J.W. Medieval and post-medieval glass technology: batch measuring practices. Glass Technology - European Journal of Glass Science and Technology Part A. Society of Glass Technology; 2002;43(1):22–27.
201.
Verita M. Comments on W.B. Stern and Y. Gerber’s ‘Postassium-calcium glass: new data and experiments’, Archaeometry, 46 (1) (2004), 137-56. Archaeometry. 2005;47(3):667–669.
202.
Mecking O. Medieval lead glass in Central Europe. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art.; 2013;55(4):640–662.
203.
Verità M. Analytical investigation of European enamelled beakers of the 13th and 14th centuries. Journal of glass studies [Internet]. 1995;37:83–98. Available from: http://www.jstor.org/stable/24190777
204.
Verita M. Analyses of Early Enamelled Venetian Glass: A Comparison with Islamic Glass. Gilded and enamelled glass from the Middle East [Internet]. London: Published for the Trustees of the British Museum by British Museum Press; 1998. p. 129–134. Available from: https://contentstore.cla.co.uk//secure/link?id=4782226b-6336-e711-80c9-005056af4099
205.
Wedepohl KH. Chemical Composition of Medieval Glass from Excavations in West Germany. Glass science and technology. 70(8):246–255.
206.
Wedepohl KH, Baumann A. Isotope composition of Medieval lead glasses reflecting early silver production in Central Europe. Mineralium Deposita. 1997;32(3):292–295.
207.
Wedepohl KH, Krueger I, Hartmann G. Medieval lead glass from North-Western Europe. Journal of glass studies [Internet]. 1995;37:65–82. Available from: http://www.jstor.org/stable/24190776
208.
Wedepohl KH, Simon K. The chemical composition of medieval wood ash glass from Central Europe. Chemie der Erde - Geochemistry. 2010;70(1):89–97.
209.
Wedepohl KH, Simon K, Kronz A. Data on 61 chemical elements for the characterization of three major glass compositions in late Antiquity and the Middle Ages. Archaeometry. Oxford: Oxford University, Research Laboratory for Archaeology and the History of Art.; 2011;53(1):81–102.
210.
Biron I, Verità M. Analytical investigation on Renaissance Venetian enamelled glasses from the Louvre collections. Journal of Archaeological Science. 2012;39(8):2706–2713.
211.
Cable M, Smedley IW. Liquidus Temperatures and Melting Characteristics of Some Early Container Glasses. Glass technology. 1987;28:94–98.
212.
Craddock PT. Scientific investigation of copies, fakes and forgeries. Oxford: Butterworth-Heinemann; 2009.
213.
Crossley DW, Huguenot Library. The performance of the glass industry in sixteenth-century England.
214.
Crossley D. An introduction to the archaeology of the glass industry: The monuments protection. Industrial Archaeology Review. 2012;34(1):24–36.
215.
De Raedt I, Janssens K, Veekman J. Compositional distinctions between 16th century ‘facon-de-Venise’ and Venetian glass vessels excavated in Antwerp, Belgium. Journal of Analytical Atomic Spectrometry [Internet]. 1999;14:493–498. Available from: http://webhost.ua.ac.be/mitac4/jaas1999b.pdf
216.
De Raedt I, Jansses K, Veekman J. On the distinction between 16th and 17th century Venetian and ‘Facon de Venise’ glass. The prehistory & history of glassmaking technology / editor Patrick McCray. 2002.
217.
Dungworth D. The Value of Historic Window Glass. The Historic Environment. 2011;2(1):21–48.
218.
Dungworth D. Historic window glass. The use of chemical analysis to date manufacture. Journal of architectural conservation. Wimbledon: Donhead Pub. in association with De Montfort University; 2012;18(1):7–25.
219.
Dungworth, David. Historic windows: investigation of composition groups with nondestructive pXRF. Glass Technology - European Journal of Glass Science and Technology Part A. Society of Glass Technology; 2012;53(5):192–197.
220.
Eramo G. The glass-melting crucibles of Derrière Sairoche (1699–1714 AD, Ct. Bern, Switzerland): a petrological approach. Journal of Archaeological Science. 2006;33(3):440–452.
221.
Dungworth D. Three and a half centuries of bottle manufacture. Industrial Archaeology Review. 2012;34(1):37–50.
222.
Freestone I. The Science of Early British Porcelain [Internet]. International Ceramics fair and seminar. 2000. p. 19–27. Available from: http://www.academia.edu/3122772/The_Science_of_Early_British_Porcelain
223.
Freestone I. The Hope Goblet Reconsidered: I Technological Considerations. Journal of Glass Studies [Internet]. 50. Available from: http://www.academia.edu/3122983/The_Hope_Goblet_Reconsidered_I_Technological_Considerations
224.
International Association for the History of Glass. Congress 2003 : London, England). The Bonus Eventus plaque - changing materials, changing perceptions. Annales du 16e Congrès de l’Association internationale pour l’histoire du verre, London, 2003 [Internet]. 2005. p. 391–395. Available from: https://www.academia.edu/24017675/The_Bonus_eventus_plaque_changing_materials_changing_perceptions_Freestone_and_Tatton-Brown_2005_
225.
Gratuze B, Janssens K. Provenance analysis of glass artefacts. Non-destructive microanalysis of cultural heritage materials / edited by K Janssens, R Van Grieken [Internet]. 2004. p. 663–712. Available from: http://ucl-primo.hosted.exlibrisgroup.com/primo_library/libweb/action/display.do?tabs=detailsTab&ct=display&fn=search&doc=UCL_LMS_DS001033181&indx=1&recIds=UCL_LMS_DS001033181&recIdxs=0&elementId=0&renderMode=poppedOut&displayMode=full&frbrVersion=&dscnt=1&scp.scps=scope%253A%2528UCL_LMS_DS%2529&frbg=&tab=local&dstmp=1377295100031&srt=rank&mode=Basic&dum=true&tb=t&vl(freeText0)=non-destructive%2520microanalysis&vid=UCL_VU1
226.
Kingery WP, P. B. Vandiver. The 18th century change in technology and style from the Famille-Verte to the Famille-Rose palette. Technology and style. Columbus, Ohio: American Ceramic Society; 1985. p. 363–381.
227.
Christine MacLeod. Accident or Design? George Ravenscroft’s Patent and the Invention of Lead-Crystal Glass. Technology and Culture. The Johns Hopkins University Press; 1987;28(4):776–803.
228.
Verità M. L’invenzione del cristallo muranese: una verifica analitica delle fonti storiche. RIVISTA DELLA STAZIONE SPERIMENTALE DEL VETRO [Internet]. 1985;15:17–29. Available from: http://www.spevetro.it/rivista.htm
229.
Wypyski MT. Technical study of Renaissance Venetian enamelled glass. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 = Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp / K Janssens . [et al], éditeurs [Internet]. 2009. p. 529–535. Available from: http://ucl-primo.hosted.exlibrisgroup.com/primo_library/libweb/action/display.do?tabs=detailsTab&ct=display&fn=search&doc=UCL_LMS_DS001457928&indx=1&recIds=UCL_LMS_DS001457928&recIdxs=0&elementId=0&renderMode=poppedOut&displayMode=full&frbrVersion=&dscnt=1&scp.scps=scope%253A%2528UCL_LMS_DS%2529&frbg=&tab=local&dstmp=1377295619403&srt=rank&mode=Basic&dum=true&tb=t&vl(freeText0)=annales%252017th%2520congress&vid=UCL_VU1
230.
Wypyski MT. Renaissance Enameled Jewelry and 19th century Renaissance Revival: Characterization of Enamel Compositions. MRS Proceedings. 2002;712.
231.
Essay titles and suggested reading lists.
232.
Nicholson, Paul T., Gerisch, Rainer, Brook, Elina, Jackson, Caroline M. Brilliant things for Akhenaten: the production of glass, vitreous materials and pottery at Amarna Site O45.1. London: Egypt Exploration Society; 2007.
233.
Paul T. Nicholson, Caroline M. Jackson and Katharine M. Trott. The Ulu Burun Glass Ingots, Cylindrical Vessels and Egyptian Glass. The Journal of Egyptian Archaeology [Internet]. Egypt Exploration Society; 1997;83:143–153. Available from: http://www.jstor.org/stable/3822462
234.
Smirniou M, Rehren TH. Direct evidence of primary glass production in late Bronze Age Amarna, Egypt. Archaeometry. oxford: Oxford University, Research Laboratory for Archaeology and the History of Art.; 2011;53(1):58–80.
235.
Henderson J. Localised production or trade? Advances in the study of cobalt blue and Islamic glasses in the Levant and Europe. Patterns and Process: A Festschrift in Honor of Dr Edward V Sayre. Smithsonian Center for Materials Research and Education (2003); 2003. p. 227–245.
236.
Gratuze et al. B. The origin of cobalt blue pigments in French glass from the thirteenth to the eighteenth centuries. Trade and discovery: the scientific study of artefacts from Post-Medieval Europe and beyond [Internet]. London: Department of Scientific Research, British Museum; 1995. p. 123–133. Available from: https://contentstore.cla.co.uk//secure/link?id=f69c1382-7336-e711-80c9-005056af4099
237.
Shortland AJ, Tite MS, Ewart I. Ancient exploitation and use of cobalt alums from the Western Oases of Egypt. Archaeometry. 2006;(1):153–168.
238.
Wood N, Tite MS, Doherty C, Gilmore B. A Technological examination of Ninth-Tenth Century Ad Abbasid blue-and-white ware from Iraq, and its comparison with Eighth Century Ad Chinese blue-and-white Sancai Ware. Archaeometry. 2007;49(4):665–684.
239.
Degryse P, Schneider J. Pliny the Elder and Sr–Nd isotopes: tracing the provenance of raw materials for Roman glass production. Journal of Archaeological Science. 2008;35(7):1993–2000.
240.
Freestone IC, Leslie KA, Thirlwall M, Gorin-Rosen Y. Strontium Isotopes in the Investigation of Early Glass Production: Byzantine and Early Islamic Glass from the Near East. Archaeometry. 2003;45(1):19–32.
241.
Wedepohl KH, Baumann A. The Use of Marine Molluskan Shells for Roman Glass and Local Raw Glass Production in the Eifel Area (Western Germany). Naturwissenschaften. 2000;87(3):129–132.
242.
Dussubieux L, Kusimba CM, Gogte V, Et al. The trading of ancient glass beads: new analytical data from South Asian and East African soda-alumina glass beads. In: Archaeometry. Archaeometry. 2008;50(5):797–821.
243.
Lankton J, Ige A, Rehren T. Early primary glass production in southern Nigeria. Journal of African Archaeology. 2006;4:111–138.
244.
Robertshaw P, Weise C. Chemical Analysis of Glass from Nupe, Nigeria. Tribus [Internet]. 2009;58:83–95. Available from: http://www.academia.edu/3370523/Chemical_Analysis_of_Glass_from_Nupe_Nigeria_with_Peter_Robertshaw_Laure_Dussubieux_James_Lankton_Rachel_Popelka-Filcoff_Michael_D._Glascock_in_Tribus_58_2010_pp._83_-95
245.
Dungworth D, Brain C. Late 17th-Century Crystal Glass: An Analytical Investigation. Journal of glass studies [Internet]. Corning, N.Y.: Corning Museum of Glass; 2009;51:111–137. Available from: http://www.jstor.org/stable/24191233
246.
Christine MacLeod. Accident or Design? George Ravenscroft’s Patent and the Invention of Lead-Crystal Glass. Technology and Culture. The Johns Hopkins University Press; 1987;28(4):776–803.
247.
Moody BE. Life of George Ravenscroft. Glass technology. 1988;29:198–210.
248.
The life of George Ravenscroft: an adendum. Glass Technology. Society of Glass Technology; 1989;30(5).
249.
Moretti C, Zecchin P. English lead crystal and Ravenscroft’s formulation: additional information from Venetian sources. Annales du 17e Congrès de l’Association Internationale pour l’Histoire du Verre, Anvers, 2006 =: Annales of the 17th Congress of the International Association for the History of Glass, 2006, Antwerp. Antwerp: University Press Antwerp; 2009. p. 431–434.
250.
Allen D. Roman Window Glass. Artefacts and archaeology: aspects of the Celtic and Roman world [Internet]. Cardiff: University of Wales Press; 2002. p. 102–111. Available from: https://contentstore.cla.co.uk//secure/link?id=a3479421-6236-e711-80c9-005056af4099
251.
DeLaine J. The baths of Caracalla: a study in the design, construction, and economics of large-scale building projects in imperial Rome. Portsmouth, R.I: Journal of Roman Archaeology; 1997.
252.
James W. Ring. Windows, Baths, and Solar Energy in the Roman Empire. American Journal of Archaeology [Internet]. Archaeological Institute of America; 1996;100(4):717–724. Available from: http://www.jstor.org/stable/506675
253.
Dungworth D. Three and a half centuries of bottle manufacture. Industrial Archaeology Review. 2012;34(1):37–50.
254.
Dugworth D, Degryse P, Schneider J. Kelp in historic glass: the application of strontium isotope analysis. Isotopes in vitreous materials. Leuven, Belgium: Leuven University Press; 2009. p. 113–130.
255.
Thomas C. McErlean. Archaeology of the Strangford Lough Kelp Industry in the Eighteenth- and Early-Nineteenth Centuries. Historical Archaeology [Internet]. Society for Historical Archaeology; 2007;41(3):76–93. Available from: http://www.jstor.org/stable/25617457
256.
Rymer L. The Scottish kelp industry. Scottish Geographical Magazine. 1974 Dec;90(3):142–152.
