Corrigendum to “Mineralogical and microstructural characterization of ceramics from the fifth and fourth millennium BC in the central plateau of Iran” [Open Ceramics, 15 (2023) 100427]

Abstract

The authors regret that there are some errors in the sample labels of Fig 6 (images. b and f) in the published manuscript. The figs. a–e all belong to ceramic sample MS.115-2 and fig. f is assigned to a ceramic sample, S.309. In accordance with the figure caption and its explanation, the sample label b. MS.611 is corrected to c. MS.115-2 and is substituted for fig. c. The image MS.611 is added to fig. b. The image MS.115-1 is substituted for fig f. Furthermore, some literature cited in the text but not included in the Reference list are added here. Reference number 33 has been revised and the in-text citation (Duttra, 2016) on page 8 is corrected to (Dutra et al., 2019).[Formula presented] [45] L. Aouba, C. Bories, M. Coutand, B. Perrin, H. Lemercier, Properties of fired clay bricks with incorporated biomasses: Cases of Olive Stone Flour and Wheat Straw residues, Construction and Building Materials 102 (2016) 7–13. [46] H. Gheisari, E. Karamian, M. Abdellahi, A novel Hydroxyapatite–Hardystonite nanocomposite ceramic, Ceramics International 41 (2015) 5967-5975. [47] C. Rathossi, Y. Pontikes, Effect of firing temperature and atmosphere on ceramics made of NW Peloponnese clay sediments: part I. Chemistry of pyrometamorphic minerals and comparison with ancient ceramics. J. Eur. Ceram. Soc. 30 (9) (2010), 1853–1866. [48] M. Majerová, R. Klement, A. Prnová, J. Kraxner, E. Bruneel, D. Galusek, Crystallization and visible–near-infrared luminescence of Bi-doped gehlenite glass. R. Soc. open sci. 5 (2018) 181667. [49] M. Bayazit, I. I. Işık, A. Issi, E. Genç, Archaeometric investigation of the late chalcolithic-early bronze age I and the 1st–2nd millennium BCE potteries from Kuriki-Turkey. Appl. Clay Sci. 126 (2016) 180–189. [50] T. P. Santos, M. F. Vaz, M.L. Pinto, A.P. Carvalho, Porosity characterization of old Portuguese ceramic tiles, Construction and Building Materials. 28 (2012), 104–110. [51] A. Hein, V. Kilikoglou, Modeling of the microstructure of ancient functional ceramics and assessment of their performance, Procedia Structural Integrity. 10 (2018), 219-226. [52] J A. Amkpa, N. A. Badarulzaman, A. Aramjat, Influence of Sintering Temperatures on Physico-Mechanical Properties and Microstructure of Refractory Fireclay Bricks, International Journal of Engineering and Technology (IJET) 8 No 6 (2016), 2588-2593. [53] G. Cultrone, E. Sebastiána, K. Elert, M. J. de la Torre, O. Cazalla, C. Rodriguez–Navarro, Influence of mineralogy and firing temperature on the porosity of bricks, Journal of the European Ceramic Society 24 (2004) 547–564. Revised reference: [33] M. Daghmehchi, B. Karimi Shahraki, H. Omrani, M. Madanipour, A. Reka, J. Nokandeh, H. Omrani Rekavandi, M.A. Emami, E.W. Sauer, Chemical and Vibrational Spectroscopic Analyses of Similar Types of Vessels from Forts on the Great Wall of Gorgan and Fortifications in its Hinterland, in: E.W. Sauer, J. Nokandeh, H. Omrani Rekavandi (Eds.), Ancient arms race: Antiquity's largest fortresses and Sasanian military networks of Northern Iran: A Joint Fieldwork Project by the Iranian Center for Archaeological Research, the Research Institute of Cultural Heritage and Tourism and the University of Edinburgh (2014–2016). British Institute of Persian Studies Archaeological Monographs Series VII. Oxbow Books, Oxford, 2022, pp. 551–576.