Cit:Ergenç.etal:2021

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Autor Ergenç, D.; Akgül, Ç. M.; Cizer, Ö.
Jahr 2021
Titel A green salt mitigation technique for archaeological bricks
Bibtex @inproceedings { Ergenç.etal:2021,

title = {A green salt mitigation technique for archaeological bricks}, booktitle = {Proceedings of SWBSS 2021 – Fifth International Conference on Salt Weathering of Buildings and Stone Sculptures}, year = {2021}, editor = {Lubelli, B.; Kamat, A.A.; Quist, W.J.}, pages = {263-272}, publisher = {TU Delft Open}, note = {In historic masonry structures, rising damp is the main source of moisture and salt. Damage due to moisture and salts is augmented after archaeological research, where decay occurs before and after excavation. This study investigates the conservation of salt-damaged fired bricks dating back to the Roman period from the archaeological site Sagalassos through desalination with a sacrificial rendering mortar incorporating bamboo biochar as a novel additive. The brick samples were first freed from salt and then exposed to controlled sodium sulfate contamination. The sacrificial rendering mortar was applied to the salt-contaminated bricks. Half of the samples was left as-is, while the other half was placed in 1 cm water to mimic rising damp conditions. This procedure was repeated several times. After each application, the salt amount at different depths was measured in the bricks. The effect of biochar on the developed mortars and the desalination efficiency of the mortars were assessed, using Dino Lite digital microscopy, SEM-EDS, XRF, ion chromatography, XRD, and TGA-DTA. Preliminary results suggest that utilization of biochar incorporating sacrificial mortar is a promising ecologically friendly solution for salt mitigation.}, key = {SWBSS 2021}, url = {https://predict.kikirpa.be/wp-content/uploads/2021/12/SWBSS2021_Procedings.pdf}, author = {Ergenç, D. and Akgül, Ç. M. and Cizer, Ö.} }

DOI
Link
Bemerkungen in: Lubelli, B.; Kamat, A.A.; Quist, W.J. (Hrsg.): Proceedings of SWBSS 2021 – Fifth International Conference on Salt Weathering of Buildings and Stone Sculptures,TU Delft Open 263-272


Eintrag in der Bibliographie

[Ergenç.etal:2021]Ergenç, D.; Akgül, Ç. M.; Cizer, Ö. (2021): A green salt mitigation technique for archaeological bricks. In: Lubelli, B.; Kamat, A.A.; Quist, W.J. (Hrsg.): Proceedings of SWBSS 2021 – Fifth International Conference on Salt Weathering of Buildings and Stone Sculptures,TU Delft Open 263-272, Webadresse.Link zu Google Scholar

Keywords[Bearbeiten]

Sacrificial mortar, bamboo biochar, Roman brick, salt, desalination

Abstract[Bearbeiten]

In historic masonry structures, rising damp is the main source of moisture and salt. Damage due to moisture and salts is augmented after archaeological research, where decay occurs before and after excavation. This study investigates the conservation of salt-damaged fired bricks dating back to the Roman period from the archaeological site Sagalassos through desalination with a sacrificial rendering mortar incorporating bamboo biochar as a novel additive. The brick samples were first freed from salt and then exposed to controlled sodium sulfate contamination. The sacrificial rendering mortar was applied to the salt-contaminated bricks. Half of the samples was left as-is, while the other half was placed in 1 cm water to mimic rising damp conditions. This procedure was repeated several times. After each application, the salt amount at different depths was measured in the bricks. The effect of biochar on the developed mortars and the desalination efficiency of the mortars were assessed, using Dino Lite digital microscopy, SEM-EDS, XRF, ion chromatography, XRD, and TGA-DTA. Preliminary results suggest that utilization of biochar incorporating sacrificial mortar is a promising ecologically friendly solution for salt mitigation.