Identification and Analysis of Ceramics Context on the Basis of Remainings of Burial Environment (Samples of Grey Ceramics Related to Iron Age) - Journal of Research on Archaeometry
year 1, Issue 1 (2015)                   JRA 2015, 1(1): 31-45 | Back to browse issues page


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B. Kasiri M, Ghorbani H, Nazarieh Y. Identification and Analysis of Ceramics Context on the Basis of Remainings of Burial Environment (Samples of Grey Ceramics Related to Iron Age). JRA. 2015; 1 (1) :31-45
URL: http://jra-tabriziau.ir/article-1-29-en.html
1- Tabriz Islamic Art University , m.kasiri@tabriziau.ac.ir
2- Birjand University
3- Tabriz Islamic Art University
Abstract:   (1942 Views)

Context of the archaeological findings is an important part of these artifacts and many useful information, regarding the provenance, application and dating of findings must be determined considering the characteristic of corresponding context. In some cases, the context of an historical objects is missing and hence, the accuracy of the information regarding the historical object is unsatisfactory. However, some types of laboratory experiments are able to provide the required information regarding the archaeological context of the object. In this study, it was tried to find the context of five gray Iron Age pottery pieces belong to the Museum of Ancient Iran. In order to identify and measure the elements in sediments and body of the samples, inductively coupled plasma-optical emission spectroscopy (ICP-OES) technique was used. Also, to identify the anions present in sediments on the samples, ion chromatography (IC) technique was employed. The results showed that, the sample MB-1 and MB-2, on the basis of elements present, have the same context, where the specifications are very close to the cemetery. Also, based on the high concentrations of calcium carbonate deposits in the chemical composition of MB-3, this sample could be related to the kitchen or floor of a residential area. Regarding the samples termed MB-4 and MB-5, as the results of elemental analysis showed the presence of some elements such as potassium, magnesium, iron, and titanium and, a positive correlation of these elements with each other, as well as a negative correlation between potassium and magnesium with Si, the context ought to be associated with fire, such as oven and grill found in the kitchen. Results of polarized light microscopy (PM) also showed a close correlation and structural similarity based on the type of tempering with gray earthenware tempering, traditionally used during the Iron Age, which are clay minerals having relatively smooth and homogeneous texture in all the samples.

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Technical Note: Original Research | Subject: Archaeometry
Received: 2015/05/22 | Accepted: 2015/07/15 | Published: 2015/09/23 | ePublished: 2015/09/23

References
1. Dunning, N. P. (1993). Ancient Maya Anthrosols, soil phosphate testing and land use. In: Foss, J. E., Timpson, M. E., Morris, M. W. (eds). Proceedings of the first interna‌tional conference on Pedo-Archaeology. Univer‌sity of Tennessee, Knoxville. Special publica‌tions, 203-211.
2. Eidt, R. C. (1985). Theoretical and practical considerations in the analysis of anthrosols. In Rapp, G., Gifford, Jr., J. A. (eds.), Archaeologi‌cal Geology. Yale University press, 155-190.
3. Goulding, K. (2000). Nitrate leaching from arable and horticultural land. Soil Use and Manage-ment, (16), 145-151.
4. Holliday, V. T., Gartner, W. G. (2007). Methods of soil P analysis in archaeology. Journal of Archaeological Science, (34), 301-333. [DOI]
5. Hutson, S. R. (2004). Dwelling and subjectification at the ancient urban center of chunchucmil, Yucatan. Mexico. Doctoral The‌sis, Department of Anthropology, University of California, Berkeley.
6. Jeffery, P., Hutchinson, G. (1983). Chemical methods of rock analysis. Third edition, 374.
7. Keeney, D. R. (1986). Nitrate in Ground Water- Agricultural Contribution and Control, In: Proceedings of the Conference on Agricultural Impacts on Ground Water. National water well as‌sociation, Dublin, Ohio, 329-351.
8. King, S. M. (2007). The spatial organization of food sharing in early post classic households: an application of soil chemistry in ancient Oaxaxa. Journal of Archaeological Science, (34), 1-16. [DOI]
9. Knudson, K. J., Frink, L., Hoffman, B. W., Price, T. D. (2004). Chemical characterization of Arctic soils: activity area analysis in contemporary Yup'ik fish camps using ICP-AES. Journal of Archaeological Science, (31), 443-456. [DOI]
10. Macphail, R. I., Cruise. G. M., Allen, M. J., Linderholm, J., Reynolds, P. (2006). Archaeological soil and pollen analysis of experimental floor deposits. Journal of Archaeological Science, (31), 175-191. [DOI]
11. May, E., Jones, M. (2006). Conservation Science: Heritage Materials. Royal Society of Chemistry. 218-225.
12. Parnell, J. J. (2001). Soil chemical analysis of activity areas in the archaeological site of Piedras Negras, Guatemala. Brigham Young University, 32-64.
13. Renfrew, C., Bahn, P. (2000). Archaeology: theories, methods and practice. Thames and Hudson, London.
14. Roth, L. T. R. (2002). Total phosphorous use area determination of Lucayan settlements, middle Caicos, Turks and Caicos Islands, British West Indies. M.A. Thesis, Department of Archaeology, University of Calgary, Alberta.
15. Wells, E. C. (2004). Investigating activity patterns in prehispanic plazas, weak acid extraction, ICP–AES analysis of anthrosols at Classic Pe‌riod El Coyote, Northwestern Honduras. Archaeometry, (46), 67-84. [DOI]
16. Woods, W. I. (1977). The quantitative analysis of soil phosphate. American Antiquity, (42), 248-252. [DOI]

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