A field guide to mortar sampling for radiocarbon dating*

[1]  I. Hajdas,et al.  COMPARISON OF THERMAL DECOMPOSITION AND SEQUENTIAL DISSOLUTION—TWO SAMPLE PREPARATION METHODS FOR RADIOCARBON DATING OF LIME MORTARS , 2021, Radiocarbon.

[2]  P. Reimer,et al.  Radiocarbon dating mortar: The identification of a Medieval Irish round tower using a multi-method inter-comparative approach , 2020 .

[3]  Brian R. Doak The Phoenicians , 2020, Ancient Israel's Neighbors.

[4]  F. Berna,et al.  Structural Characterization and Thermal Decomposition of Lime Binders Allow Accurate Radiocarbon Age Determinations of Aerial Lime Plaster , 2020, Radiocarbon.

[5]  I. Hajdas,et al.  Delayed Hardening and Reactivation of Binder Calcite, Common Problems in Radiocarbon Dating of Lime Mortars , 2020, Radiocarbon.

[6]  D. Michalska Influence of different pretreatments on mortar dating results , 2019, Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms.

[7]  D. Michalska,et al.  Modeled and Measured Carbon Isotopic Composition and Petrographically Estimated Binder-Aggregate Ratio—Recipe for Binding Material Dating? , 2019, Radiocarbon.

[8]  Graciela Ponce-Antón,et al.  Hydrotalcite and Hydrocalumite in Mortar Binders from the Medieval Castle of Portilla (Álava, North Spain): Accurate Mineralogical Control to Achieve More Reliable Chronological Ages , 2018, Minerals.

[9]  Lynne C. Lancaster,et al.  Radiocarbon Dating Historical Mortars: Lime Lumps and/or Binder Carbonate? , 2018, Radiocarbon: An International Journal of Cosmogenic Isotope Research.

[10]  F. Marzaioli,et al.  Radiocarbon Dating of Mortars with a Pozzolana Aggregate Using the Cryo2SoniC Protocol to Isolate the Binder , 2017, Radiocarbon.

[11]  D. Michalska,et al.  Methodological Aspect of Mortars Dating (Poznań, Poland, MODIS) , 2017, Radiocarbon.

[12]  I. Hajdas,et al.  Preparation and Dating of Mortar Samples—Mortar Dating Inter-Comparison Study (MODIS) , 2017, Radiocarbon.

[13]  A. Langella,et al.  Radiocarbon dating of mortars: Contamination effects and sample characterisation. The case-study of Andalusian medieval castles (Jaén, Spain) , 2017 .

[14]  D. Ergenç,et al.  Characterization of concrete from Roman buildings for public spectacles in Emerita Augusta (Mérida, Spain) , 2018, Archaeological and Anthropological Sciences.

[15]  K. Al-Bashaireh Use of Lightweight Lime Mortar in the Construction of the West Church of Umm el-Jimal, Jordan: Radiocarbon Dating and Characterization , 2016, Radiocarbon.

[16]  A. Lichtenberger,et al.  Radiocarbon analysis of mortar from Roman and Byzantine water management installations in the Northwest Quarter of Jerash, Jordan , 2015 .

[17]  J. Heinemeier,et al.  14C chronology of the oldest Scandinavian church in use. An AMS/PIXE study of lime lump carbonate in the mortar , 2014 .

[18]  J. Heinemeier,et al.  19 Years of Mortar Dating: Learning from Experience , 2014, Radiocarbon.

[19]  G. Ventura,et al.  Geochemical fingerprints of volcanic materials: Identification of a pumice trade route from Pompeii to Rome , 2013 .

[20]  R. Ball,et al.  Identification, Extraction, and Preparation of Reliable Lime Samples for 14C Dating of Plasters and Mortars with the “Pure Lime Lumps” Technique , 2012, Radiocarbon.

[21]  G. Hodgins,et al.  Lime Mortar and Plaster: A Radiocarbon Dating Tool for Dating Nabatean Structures in Petra, Jordan , 2012, Radiocarbon.

[22]  I. Hajdas,et al.  Roman Ruins as an Experiment for Radiocarbon Dating of Mortar , 2012, Radiocarbon: An International Journal of Cosmogenic Isotope Research.

[23]  S. Weiner,et al.  Plaster Characterization at the PPNB Site of Yiftahel (Israel) Including the Use of 14C: Implications for Plaster Production, Preservation, and Dating , 2012, Radiocarbon.

[24]  X. Murelaga,et al.  Historic Lime-Mortar 14C Dating of Santa María La Real (Zarautz, Northern Spain): Extraction of Suitable Grain Size for Reliable 14C Dating , 2012, Radiocarbon.

[25]  G. Hodgins,et al.  AMS 14C dating of organic inclusions of plaster and mortar from different structures at Petra-Jordan , 2011 .

[26]  F. Marzaioli,et al.  Mortar radiocarbon dating: preliminary accuracy evaluation of a novel methodology. , 2011, Analytical chemistry.

[27]  Lw Hobbs,et al.  Cementitious materials of the ancient world , 2011 .

[28]  Marie D. Jackson,et al.  Mid‐Pleistocene pozzolanic volcanic ash in ancient Roman concretes , 2010 .

[29]  E. Boaretto Dating Materials in Good Archaeological Contexts: The Next Challenge for Radiocarbon Analysis , 2009, Radiocarbon.

[30]  T. Goslar,et al.  14C Dating of Carbonate Mortars from Polish and Israeli Sites , 2009, Radiocarbon.

[31]  A. Bayliss Rolling Out Revolution: Using Radiocarbon Dating in Archaeology , 2009, Radiocarbon.

[32]  G. Quarta,et al.  Radiocarbon Dating of Lumps from Aerial Lime Mortars and Plasters: Methodological Issues and Results from San Nicolò of Capodimonte Church (Camogli, Genoa, Italy) , 2009, Radiocarbon.

[33]  S. Weiner,et al.  Differentiating between anthropogenic calcite in plaster, ash and natural calcite using infrared spectroscopy: implications in archaeology , 2008 .

[34]  J. Heinemeier,et al.  Mortar Dating Using AMS 14C and Sequential Dissolution: Examples from Medieval, Non-Hydraulic Lime Mortars from the Åland Islands, SW Finland , 2007, Radiocarbon.

[35]  M. Żurakowska,et al.  Issue of Actual Chronology of a Romanesque Chapel at the Wlen Castle (Lower Silesia, Poland) in the Light of Mortar Radiocarbon Dating , 2007 .

[36]  Lynne C. Lancaster Concrete Vaulted Construction in Imperial Rome: Innovations in Context , 2005 .

[37]  Lynne C. Lancaster,et al.  Dating Ancient Mortar , 2003, American Scientist.

[38]  Antonia Moropoulou,et al.  Investigation of the technology of historic mortars , 2000 .

[39]  A. Moropoulou,et al.  Characterization of structural byzantine mortars by thermogravimetric analysis , 1998 .

[40]  K. van der Borg,et al.  Radiocarbon Dating of Lime Fractions and Organic Material from Buildings , 1992, Radiocarbon.

[41]  L. Tubbs,et al.  The use of AMS for the dating of lime mortars , 1990 .

[42]  E. Sonninen,et al.  Dating of mortar and bricks: an example from Finland , 1989 .

[43]  E. Keppens,et al.  Isotopic Fractionation of Oxygen and Carbon in Lime Mortar Under Natural Environmental Conditions , 1989, Radiocarbon.

[44]  J. Ambers Stable carbon isotope ratios and their relevance to the determination of accurate radiocarbon dates for lime mortars , 1987 .

[45]  S. Filippakis,et al.  RADIOCARBON DATING OF MORTARS FROM ANCIENT GREEK PALACES , 1987 .

[46]  C. Pachiaudi,et al.  The Influence of Contaminating (Fossil) Carbonate and the Variations of δ13C in Mortar Dating , 1986, Radiocarbon.

[47]  C. Pachiaudi,et al.  Isotopic Fractionation of Carbon During CO2 Absorption by Mortar , 1986, Radiocarbon.

[48]  J. Oleson,et al.  The Caesarea Ancient Harbor Excavation Project (C.A.H.E.P.): Preliminary Report on the 1980–1983 Seasons , 1984 .

[49]  R. Folk,et al.  Successful Technique for Dating of Lime Mortar by Carbon-14 , 1976 .

[50]  M. Baxter,et al.  Radiocarbon Dating of Mortars , 1970, Nature.

[51]  F. Lea The chemistry of cement and concrete , 1970 .

[52]  J. Labeyrie,et al.  Dating of Old Mortars by the Carbon-14 Method , 1964, Nature.

[53]  J. Liversidge Ancient Roman Construction in Italy from the Prehistoric Period to Augustus , 1948, Nature.