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100   $a20090508d2009      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aIsotopes in vitreous materials$b[electronic resource] /$fedited by Patrick Degryse, Julian Henderson and Greg Hodgins
210   $aLeuven, Belgium $cLeuven University Press$dc2009
215   $a1 online resource (166 p.)
225 1 $aStudies in archaeological sciences ;$v1
300   $aDescription based upon print version of record.
311   $a90-5867-690-0 
320   $aIncludes bibliographical references.
327   $aIsotopesin Vitreous Materials; Table of Contents; List of Illustrations; List of Tables; Isotopes in vitreous materials, a state-of-the-art and perspectives; Introduction; Possibilities: relevance of the technique; Contributions in this volume; Impossibilities: limitations of the technique; Accessibility: new techniques; Perspectives; References; Isotopic composition of glass from the Levant and the south-eastern Mediterranean Region; Introduction; Raw materials; Neodymium isotopes; Oxygen isotopes; Lead isotopes; Predictive provenancing: HIMT glass
327   $aComparison and discrimination: plant ash glassDiscussion and conclusion; Acknowledgements; References; Appendix: analytical methods; Neodymium and strontium isotopes in the provenance determination of primary natron glass production; Introduction; Glass provenancing; Glass provenancing and elemental analysis; Glass provenancing and isotopes; Methodology; Sampling; Chemical analysis; Archaeological context; Sagalassos; Maastricht; Kelemantia; Bocholtz; Tienen; Results; Discussion; Conclusion; Acknowledgements; References; The provenance of Syrian plant ash glass: an isotopic approach
327   $aIntroductionGlass production at al-Raqqa; The principles of isotope analysis and how isotopes contribute; Methodology; Results; Strontium; Neodymium; Discussion; Conclusions; Acknowledgements; References; The implications of lead isotope analysis for the source of pigments in Late Bronze Age Egyptian vitreous materials; Introduction; Results; Pigments: Egyptian blue and green frit; Glasses; Faience; Discussion; Conclusions; Acknowledgements; References; Kelp in historic glass: the application of strontium isotope analysis; Introduction
327   $aStrontium isotopic ratios in nature and their use in geology and related disciplinesStrontium isotope analysis of skeletal material; Strontium isotope analysis of glass; Where does the strontium in glass come from?; Strontium in some post-medieval glass; Samples and Methods; Results; Conclusion; References; Medieval and postmedieval Hispano-Moresque glazed ceramics: new possibilities of characterization by means of lead isotope ratio determination by Quadrupole ICP-MS; Introduction; Experimental; Materials and methods; Sample preparation; Results and discussion; Conclusions; Acknowledgements
327   $aReferencesPLS Regression to Determine Lead Isotope Ratios of Roman Lead Glazed Ceramics by Laser Ablation TOF-ICP-MS; Introduction; Experimental; PLS Modeling; Standards; Samples; Instrumentation; Data Reduction Procedures; Results; Calibration; Lead-Glazed Samples; Discussion; Calibration; Measurement of Lead Isotope Ratios of Roman Lead Glazes; Conclusion; Acknowledgements; References; List of Authors; The Editors
330   $aFor all archaeological artefactual evidence, the study of the provenance, production technology and trade of raw materials must be based on archaeometry. Whereas the study of the provenance and trade of stone and ceramics is already well advanced, this is not necessarily the case for ancient glass. The nature of the raw materials used and the geographical location of their transformation into artefacts often remain unclear. Currently, these questions are addressed by the use of radiogenic isotope analysis. With the specific information the technique provides, archaeologists can further their u
410  0$aStudies in archaeological sciences ;$v1.
606   $aArchaeometry$xMethodology
606   $aGlass$xAnalysis
608   $aElectronic books.
615  0$aArchaeometry$xMethodology.
615  0$aGlass$xAnalysis.
676   $a930.1
701   $aDegryse$b Patrick$0860623
701   $aHenderson$b Julian$f1953-$068178
701   $aHodgins$b Gregory$0923537
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910459794003321
996   $aIsotopes in vitreous materials$92072423
997   $aUNINA