Structural Analysis of Some Pottery Fragments Belonging to Hamangia (Phase III) Culture

[1] Voinea V, Băjenaru C, Lascu M, Nopcea C, Irimia A, Măiță M, Gheorghe A, Complexe Hamangia din situl Techirghiol Dealul Minerva – Paloda. Cercetări arheologice preventive 2020 (Raport preliminar). Pontica 2021; 54: 12-44. Search in Google Scholar

[2] Balasse M, Tornero C, Bréhard S, Ughetto-Monfrin J, Voinea V, Bălășescu A, Cattle and Sheep Herding at Cheia, Romania, at the Turn of the Fifth Millennium cal BC. A View from Stable Isotope Analysis. Proceedings of the British Academy 2014; 198: 115–142. Search in Google Scholar

[3] Voinea V, Neagu G, Ceramica Hamangia III. Pontica 2006; 42: 9-25. Search in Google Scholar

[4] Carozza L, Micu C, Bălășescu A, Ailincăi S, Burens A, Gâza O, Mănăilescu C, Pour une relecture des collections archéologiques néolithiques et chalcolithiques dans la zone de Hamangia-Baia: nouvelles données chronologiques relatives aux recherches conduites par Dumitru Berciu. Cercetări Arheologice 2020; 27: 141-161. Search in Google Scholar

[5] Nodari L, Maritan L, Mazzoli C, Russo U, Sandwich structures in the Etruscan-Padan type pottery. Applied Clay Science 2004; 27(1-2): 119–128. Search in Google Scholar

[6] Tite, M.S. Ceramic production, provenance and use - A review. Archaeometry 2008, 50, 216–231. Search in Google Scholar

[7] Estaugh N, Walsh V, Chaplin T, Siddall R. 2008. Pigment Compendium A Dictionary and Optical Microscopy of Historical Pigments. Elsevier, Amsterdam. Search in Google Scholar

[8] Giuliani G, Groat L, Geology of corundum and emerald gem deposits: a review. Gems & Gemology 2019; 55(4): 464–489. Search in Google Scholar

[9] Wei C, Liu X, Niu J, Feng L, Yue H, High temperature mechanical properties of laminated ZrB2–SiC based ceramics. Ceram Int2016; 42:18148–18153. Search in Google Scholar

[10] Harabi A, Zaiou S, Guechi A, Foughali L, Harabi E, Karboua NE, Zouai S, Mezahi FZ, Guerfa F, Mechanical properties of anorthite based ceramics prepared from kaolin DD2 and calcite. Ceramica2017; 63: 311-317. Search in Google Scholar

[11] Săndulescu M. 1995, Dobrogea within the Carpathian foreland. In Grădinaru, E. (ed.) Field Guidebook. Central and North Dobrogea. IGCP Project No.369, Comparative Evolution of PeriTethyan Rift Basins, Romania, Oct.1-4, 1-4. Search in Google Scholar

[12] Seghedi A, Oaie G, Aniţăi N, 2018. Dobrogea – geological heritage. GeoEcoMar Publ. House, București. Search in Google Scholar

[13] Ferguson RB, Traill RJ, Taylor WH, The crystal structures of low-temperature and high-temperature albites. Acta Crystallographica 1958; 11: 331–348 Search in Google Scholar

[14] Shafei L, Adhikari P, Ching W, DFT Study of Electronic Structure and Optical Properties of Kaolinite, Muscovite, and Montmorillonite. Crystals 2021; 11, 618. Search in Google Scholar

[15] Guidotti CV, Compositional variation of muscovite as a function of metamorphic grade and assemblage in metapelites from N.W. Maine. Contr. Mineral. and Petrol. 1973; 42: 33–42. Search in Google Scholar

[16] Damjanović L, Holclajtner-Antunović I, Mioč UB, Bikić V, Milanović D, Evans IR, Archaeometric study of medieval pottery excavated at Stari (Old) Ras, Serbia. Journal of Archaeological Science 2011; 38(4): 818–828. Search in Google Scholar

[17] Klein C, Some Precambrian banded iron-formations (BIFs) from around the world: Their age, geologic setting, mineralogy, metamorphism, geochemistry, and origin. Am. Mineral 2005; 90: 1473–1499. Search in Google Scholar

[18] Gruner JW, The composition and structure of minnesotaite, a common iron silicate in iron formations. Amer. Mineral 1944; 29: 363-372. Search in Google Scholar

[19] Klein C, 1983. Diagnesis and metamorphism of precambrian banded iron-formation., in: Iron-Formation Facts and Problems. Edited by A.F. Trendall, R.C. Morris. pp. 417–468. Search in Google Scholar

[20] Konhauser KO, Planavsky NJ, Hardisty DS, Robbins LJ, Warchola TJ, Haugaard R, Lalonde SV, Partin CA, Oonk PBH, Tsikos H, Lyons TW, Bekker A, Johnson CM, Iron formations: A global record of Neoarchaeanto Palaeoproterozoic environmental history. Earth-Science Rev. 2017; 172: 140–177. Search in Google Scholar

[21] Lempart-Drozd M, Błachowski A, GumsleyA, Ciesielska Z, Thermal decomposition of minnesotaiteand dehydrogenation during Fe2+ oxidation, with implications for redox reactions in Banded Iron Formations. Chemical Geology 2022; 601: 120867. Search in Google Scholar