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Archaeological and Anthropological Sciences

, Volume 11, Issue 9, pp 5065–5080 | Cite as

The efficiency of nanolime and dibasic ammonium phosphate in the consolidation of beige limestone from the Pasargadae World Heritage Site

  • Atefeh ShekoftehEmail author
  • Eduardo Molina
  • Lucía Rueda-Quero
  • Anna Arizzi
  • Giuseppe Cultrone
Original Paper
  • 40 Downloads

Abstract

The limestone used at the Pasargadae World Heritage Site in Iran, an outstanding open-air architectural heritage site dating from the Achaemenid period (sixth century BC), has suffered weathering due to interaction with the environment. It was built out of beige limestone that today shows scaling and pitting decay patterns. Two inorganic consolidating products that are very promising: nanolime and dibasic ammonium phosphate (DAP) were considered for the consolidation of the limestone. Consolidation treatments were conducted on samples from a quarry and applied using a paintbrush with 50% nanolime dispersion in isopropyl alcohol and 1.0 M DAP water solution. Superficial consolidation was evaluated by means of a micro-drilling resistance test, and color changes were assessed by spectrophotometry. The microstructure of the treated samples was observed using FE-SEM. The efficacy of the two consolidation treatments was also assessed by testing their hydric properties and durability (hydric tests, freeze-thaw, and salt crystallization cycles). The compactness in the altered samples was monitored by measuring the ultrasound propagation velocity. We found that the superficial resistance increased in a similar way with both treatments. However, spectrophotometry revealed a yellowish color in the samples treated with DAP. During FE-SEM observations, some diffused microcracks were detected on the surface of DAP treatment. When subjected to accelerated aging tests, both treatments managed to postpone the formation of the first microcrack during the freeze-thaw test and both showed outstanding stability during salt crystallization cycles. In conclusion, the nanolime product seems to be more compatible with beige limestone because it does not affect its aesthetic qualities (color, lightness, and a homogeneous layer formed on the surface of the stone). Moreover, previous research found that lime has a low propensity for biological growth. This supports its use as a consolidating product for the stone used in open-air archeological sites that are prone to microbial growth, such as the beige stone used in the Pasargadae WHS.

Keywords

Inorganic Consolidant Nanolime DAP HAP Limestone consolidation Pasargadae 

Notes

Acknowledgments

We would like to thank the Iranian Ministry of Science, Research and Technology for financial support. We further thank the Centro de Instrumentación Científica (CIC; University of Granada, Spain) for the assistance with SEM-EDX analyses; Prof. Carlos Rodriguez-Navarro, Prof. Eduardo Sebastián Pardo, Dr. Encarnación Ruiz Agudo, and Dr. Alejandro Burgos-Cara from the Department of Mineralogy and Petrology of the University of Granada, Spain; Georgios Tavlaridis (Independent Conservation Scientist); Dr. Omid Oudbashi and Dr. Hossein Ahmadi (Art University of Isfahan, Iran); Dr. Mehdi Yazdi (University of Isfahan, Iran); Dr. Hamid Fadaei (Administrator of the Persepolis WHS, Fars, Iran); Farzaneh Gerami, Ali Taghva and Hamidreza Karami (Foundation of Pasargadae WHS, Iran).

Funding information

This study received financial support from Research Group RNM179 of the Junta de Andalucía and Research Project MAT2016-75889-R.

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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019
corrected publication 2019

Authors and Affiliations

  1. 1.Department of Conservation of Cultural and Historical Properties, Faculty of ConservationArt University of IsfahanIsfahanIran
  2. 2.Departamento de Ingeniería Estructural y Geotécnica, Escuela de IngenieríaPontificia Universidad Católica de ChileSantiagoChile
  3. 3.Centro de Excelencia en Geotermia de Los Andes (Cega, Fondap-Conicyt)Universidad de ChileSantiagoChile
  4. 4.Department of SculptureUniversity of GranadaGranadaSpain
  5. 5.Department of Mineralogy and Petrology, Faculty of ScienceUniversity of GranadaGranadaSpain

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