Wood is made of organic components including cellulose, hemicellulose, and lignin with traces of inorganics. Thus, it is possible to investigate a wooden material status using both molecular spectroscopies and elemental analysis. Degradable intrinsic of wood causes having it rarely found through archaeological excavations of ancient sites. Therefore, archeologists will be delighted with finding an intact wooden tool because it enables them to configure virtually the structure of the other ancient stuff found at the same place and conclude meaningfully about their application taking into account the location of excavation. In this article, identification of a piece of wooden rod discovered in Chogha Zanbil (Al-Untash-Napirisha) was performed using an optical microscope and SEM, EDS and, FTIR. Optical microscope helped to find the genus of the wood which was further confirmed by SEM images. Elemental analysis results of the rod using EDS were in accordance with the previous findings in the literature. FTIR worked out all the bonds between building up atoms prooving the wooden structure. These characterizations have revealed that the wood belongs to date palm tree. In fact, this piece of wood was being used to hold the cone-shaped glass on the door surface of the temple in the middle Elamite era (1280 B.C).
Published in | International Journal of Archaeology (Volume 9, Issue 2) |
DOI | 10.11648/j.ija.20210902.17 |
Page(s) | 79-85 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Middle Elamite, Wooden Holder, Date Palm, Microscopic Studies, FTIR, SEM-EDS
[1] | Rowell, R. M., Pettersen, R., Han, J. S., Rowell, J. S., & Tshabalala, M. A. (2005). Cell wall chemistry. Handbook of wood chemistry and wood composites, 2. |
[2] | Vidal-Matutano, P., Rodríguez-Rodríguez, A., Del Cristo González-Marrero, M., Morales, J., Henríquez-Valido, P., & Moreno-Benítez, M. A. (2020). Woodworking in the cliffs? Xylological and morpho-technological analyses of wood remains in the Prehispanic granaries of Gran Canaria (Canary Islands, Spain). Quaternary International. |
[3] | Biancamaria Arangurena, Anna Revedinb, Nicola Amicoc, Fabio Cavullid, Gianna Giachie, Stefano Grimaldid, Nicola Macchionie, and Fabio Santaniellod. (2018). Wooden tools and fire technology in the early Neanderthal site of Poggetti Vecchi (Italy). PNAS, 115 (9), 2054–2059. |
[4] | Adam P. Pinder, Ian Panter, Geofrey D. Abbott & Brendan J. Keely. (2017). Deterioration of the Hanson Logboat: chemical and imaging assessment with removal of polyethylene glycol conserving agent. Nature, 7 (13697). |
[5] | Charlotte Gjelstrup Björdal. (2012). Microbial degradation of waterlogged archaeological wood. Journal of Cultural Heritage, 13S, S118–S122. |
[6] | J. Tintnera, E. Smidta, C. Aumüllera, P. Martina, F. Ottnerb, K. Wriessnigb, H. Reschreiterc. (2018). Taphonomy of prehistoric bark in a salt environment at the archaeological site in Hallstatt, Upper Austria – An analytical approach based on FTIR spectroscopy. Vibrational Spectroscopy, 97, 39–43. |
[7] | Karin Fackler, Manfred Schwanninger. (2010). Polysacharide degradation and lignin modification during brown rot of spruce wood: a polarised Fourier transform near infra red study. J. Near Infrared Spectrosc. 18, 403-416. |
[8] | Jeannette Jacqueline Łucejko, Marco Mattonai, Magdalena Zborowska, Diego Tamburini, Grzegorz Cofta, Emma Cantisani, Jozef Kúdela, Caroline Cartwright, Maria Perla Colombini, Erika Ribechini, Francesca Modugno. (2018). Deterioration effects of wet environments and brown rot fungus Coniophora puteana on pine wood in the archaeological site of Biskupin (Poland). Microchemical Journal. 138, 132–146. |
[9] | L. Darchuk, G. Gatto Rotondo, M. Swaenenb, A. Worobiec, Z. Tsybrii, Y. Makarovskaa, R. Van Grieken. (2011). Composition of prehistoric rock-painting pigments from Egypt (Gilf Kébir area). Spectrochimica Acta Part A. 83, 34–38. |
[10] | Diego Tamburini, Jeannette Jacqueline Łucejko, Francesca Modugno, Maria Perla Colombini, Pasquino Pallecchi, Gianna Giachi. (2014). Microscopic techniques (LM, SEM) and a multi-analytical approach (EDX, FTIR, GC/MS, Py-GC/MS) to characterise the decoration technique of the wooden ceiling of the House of the Telephus Relief in Herculaneum (Italy). Microchemical Journal. 116, 7–14. |
[11] | Willcox, G. (1992). Timber and trees: ancient exploitation in the Middle East: evidence from plant remains. Bulletin on Sumerian Agriculture, 6, 1-31. |
[12] | Grayson, A. K. (1975). Babylonian historical-literary texts: University of Toronto Press. |
[13] | Wiseman, D. J. (1983). Mesopotamian gardens. Anatolian studies, 137-144. |
[14] | Popenoe, W. (1924). Economic fruit-bearing plants of Ecuador. Plant studies, chiefly tropical American. |
[15] | Van De Mieroop, M. (1992). Society and enterprise in old Babylonian Ur: Reimer. |
[16] | Van de Mieroop, M. (1987). Crafts in the Early Isin Period: A study of the Isin craft archive from the reigns of Išbi-Erra and šū-ilišu: Dep. Orientalistiek. |
[17] | Collon, D. (1969). Mesopotamian columns. Journal of the Ancient Near Eastern Society, 2 (1), 2119. |
[18] | Djamali, M., Ponel, P., Andrieu-Ponel, V., de Beaulieu, J.-L., Guibal, F., Miller, N. F., Lak, R. (2010). Notes on arboricultural and agricultural practices in ancient Iran based on new pollen evidence. Paléorient, 175-188. |
[19] | Mecquenem, R. d., & Michalon, J. (1953). Recherches à Tchogha Zembil. Mémoires de la Mission Archéologique en Iran. |
[20] | Ghirshman, R. (1966). Tchoga Zanbil II. La ziggurat. |
[21] | http://www.palmito-info.net/ |
[22] | Zhuang, J., Li, M., Pu, Y., Ragauskas, A. J., & Yoo, C. G. (2020). Observation of Potential Contaminants in Processed Biomass Using Fourier Transform Infrared Spectroscopy. Applied Sciences, 10 (12), 4345. |
[23] | Yin, Y., Yin, H., Wu, Z., Qi, C., Tian, H., Zhang, W., Feng, L. (2019). Characterization of Coals and Coal Ashes with High Si Content Using Combined Second-Derivative Infrared Spectroscopy and Raman Spectroscopy. Crystals, 9 (10), 513. |
[24] | Boeriu, C. G., Bravo, D., Gosselink, R. J., & van Dam, J. E. (2004). Characterization of structure-dependent functional properties of lignin with infrared spectroscopy. Industrial crops and products, 20 (2), 205-218. |
[25] | Galiwango, E., Rahman, N. S. A., Al-Marzouqi, A. H., Abu-Omar, M. M., & Khaleel, A. A. (2019). Isolation and characterization of cellulose and α-cellulose from date palm biomass waste. Heliyon, 5 (12), e02937. |
[26] | Afzaluddin, A., Jawaid, M., Salit, M. S., & Ishak, M. R. (2019). Physical and mechanical properties of sugar palm/glass fiber reinforced thermoplastic polyurethane hybrid composites. Journal of Materials Research and Technology, 8 (1), 950-959. |
[27] | Amroune, S., Bezazi, A., Belaadi, A., Zhu, C., Scarpa, F., Rahatekar, S., & Imad, A. (2015). Tensile mechanical properties and surface chemical sensitivity of technical fibers from date palm fruit branches (Phoenix dactylifera L.). Composites Part A: Applied Science and Manufacturing, 71, 95-106. |
[28] | Furuta Y., Aizawa H., Yano H., Norimoto M. (1997). Thermal-softening properties of water-swollen wood IV. The effects of chemical cconstituents of the cell wall on the thermal-softening properties of wood. J Jpn Wood Res Soc, 43, 725–30. |
[29] | Oushabi, A., Sair, S., Abboud, Y., Tanane, O., & Bouari, A. (2015). Natural thermal-insulation materials composed of renewable resources: characterization of local date palm fibers (LDPF). J. Mater. Environ. Sci, 6 (12), 3395-3402. |
[30] | Saleh, T. A., & Gupta, V. K. (2014). Processing methods, characteristics, and adsorption behavior of tire-derived carbons: a review. Advances in colloid and interface science, 211, 93-101. |
APA Style
Navid Salehvand, Shamim Amiri, Sara Hosseinzadegan, Mohammad Khazaei. (2021). Microscopic Studies on Wooden Holder of Decorative Glass Remaining from Middle Elamite Era (1280 B.C). International Journal of Archaeology, 9(2), 79-85. https://doi.org/10.11648/j.ija.20210902.17
ACS Style
Navid Salehvand; Shamim Amiri; Sara Hosseinzadegan; Mohammad Khazaei. Microscopic Studies on Wooden Holder of Decorative Glass Remaining from Middle Elamite Era (1280 B.C). Int. J. Archaeol. 2021, 9(2), 79-85. doi: 10.11648/j.ija.20210902.17
AMA Style
Navid Salehvand, Shamim Amiri, Sara Hosseinzadegan, Mohammad Khazaei. Microscopic Studies on Wooden Holder of Decorative Glass Remaining from Middle Elamite Era (1280 B.C). Int J Archaeol. 2021;9(2):79-85. doi: 10.11648/j.ija.20210902.17
@article{10.11648/j.ija.20210902.17, author = {Navid Salehvand and Shamim Amiri and Sara Hosseinzadegan and Mohammad Khazaei}, title = {Microscopic Studies on Wooden Holder of Decorative Glass Remaining from Middle Elamite Era (1280 B.C)}, journal = {International Journal of Archaeology}, volume = {9}, number = {2}, pages = {79-85}, doi = {10.11648/j.ija.20210902.17}, url = {https://doi.org/10.11648/j.ija.20210902.17}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ija.20210902.17}, abstract = {Wood is made of organic components including cellulose, hemicellulose, and lignin with traces of inorganics. Thus, it is possible to investigate a wooden material status using both molecular spectroscopies and elemental analysis. Degradable intrinsic of wood causes having it rarely found through archaeological excavations of ancient sites. Therefore, archeologists will be delighted with finding an intact wooden tool because it enables them to configure virtually the structure of the other ancient stuff found at the same place and conclude meaningfully about their application taking into account the location of excavation. In this article, identification of a piece of wooden rod discovered in Chogha Zanbil (Al-Untash-Napirisha) was performed using an optical microscope and SEM, EDS and, FTIR. Optical microscope helped to find the genus of the wood which was further confirmed by SEM images. Elemental analysis results of the rod using EDS were in accordance with the previous findings in the literature. FTIR worked out all the bonds between building up atoms prooving the wooden structure. These characterizations have revealed that the wood belongs to date palm tree. In fact, this piece of wood was being used to hold the cone-shaped glass on the door surface of the temple in the middle Elamite era (1280 B.C).}, year = {2021} }
TY - JOUR T1 - Microscopic Studies on Wooden Holder of Decorative Glass Remaining from Middle Elamite Era (1280 B.C) AU - Navid Salehvand AU - Shamim Amiri AU - Sara Hosseinzadegan AU - Mohammad Khazaei Y1 - 2021/12/24 PY - 2021 N1 - https://doi.org/10.11648/j.ija.20210902.17 DO - 10.11648/j.ija.20210902.17 T2 - International Journal of Archaeology JF - International Journal of Archaeology JO - International Journal of Archaeology SP - 79 EP - 85 PB - Science Publishing Group SN - 2330-7595 UR - https://doi.org/10.11648/j.ija.20210902.17 AB - Wood is made of organic components including cellulose, hemicellulose, and lignin with traces of inorganics. Thus, it is possible to investigate a wooden material status using both molecular spectroscopies and elemental analysis. Degradable intrinsic of wood causes having it rarely found through archaeological excavations of ancient sites. Therefore, archeologists will be delighted with finding an intact wooden tool because it enables them to configure virtually the structure of the other ancient stuff found at the same place and conclude meaningfully about their application taking into account the location of excavation. In this article, identification of a piece of wooden rod discovered in Chogha Zanbil (Al-Untash-Napirisha) was performed using an optical microscope and SEM, EDS and, FTIR. Optical microscope helped to find the genus of the wood which was further confirmed by SEM images. Elemental analysis results of the rod using EDS were in accordance with the previous findings in the literature. FTIR worked out all the bonds between building up atoms prooving the wooden structure. These characterizations have revealed that the wood belongs to date palm tree. In fact, this piece of wood was being used to hold the cone-shaped glass on the door surface of the temple in the middle Elamite era (1280 B.C). VL - 9 IS - 2 ER -