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12 - Weathering hazards

Published online by Cambridge University Press:  10 January 2011

By
Andrew S. Goudie  and
Heather Viles
Edited by
Irasema Alcántara-Ayala  and
Andrew S. Goudie
Irasema Alcántara-Ayala
Affiliation:
Universidad Nacional Autonoma de Mexico, Mexico City
Andrew S. Goudie
Affiliation:
St Cross College, Oxford
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Summary

Introduction

Like many geomorphological processes, weathering can pose a hazard if it affects humans, their property and livelihoods. Unlike many geomorphological processes that are known to cause a hazard, such as landslides, avalanches and coastal erosion, weathering is generally slow and small scale, though once thresholds have been breached or humans have accelerated the processes involved, weathering can have dramatic results (such as the rapid, catastrophic weathering of limestone facades recognised by Smith and Viles,2006). The slow rate and small-scale nature of weathering means that it is often overlooked in hazard research, but it can have serious economic effects as well as being capable of irreparably damaging items of our cultural heritage. For example, relatively minor (in geomorphological terms) rates of weathering can disfigure valuable carving and statuary or induce fragments of stonework to fall from a facade, which are capable of causing injury or death. It can also contribute to more catastrophic events such as rockfalls (Figure 12.1) and rockslides (Matsuoka and Sakai, 1999; Jaboyedoff et al., 2004; Borrelli et al., 2007) and promote landslides in deeply weathered materials (Durgin, 1977) and in clays (Gullà et al., 2006). Chemical weathering may also pose hazards to human health by liberating toxic chemicals (e.g. excessive amounts of arsenic, fluoride, heavy metals etc. from bedrock and mine waste) (Islam et al., 2000; Saxena and Ahmed, 2001; Dang et al., 2002).

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Geomorphological Hazards and Disaster Prevention , pp. 145 - 160
Publisher: Cambridge University Press
Print publication year: 2010

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References

Akiner, S., Cooke, R. U. and French, R. A. (1992). Salt damage to Islamic monuments in Uzbekistan. Geographical Journal, 158, 257–272.CrossRefGoogle Scholar
Albouy, M., Deletie, P., Haguenauer, B.et al. (1993). Petra, la cité rose des sables. La pathologie des grès et leur traitement dans la perspective d'une préservation et d'une restauration des monuments. In Thiel, M. J. (ed.), Conservation of Stone and Other Materials. London: E. & F. Spon, pp. 376–385.Google Scholar
Allison, R. J. and Bristow, G. E. (1999). The effects of fire on rock weathering: some further considerations of laboratory experimental simulation. Earth Surface Processes and Landforms, 24, 707–713.3.0.CO;2-Z>CrossRefGoogle Scholar
André, M.-F., Etienne, S., Mercier, D., Vautier, F. and Voldoire, O. (2008). Assessment of sandstone deterioration at Ta Keo temple (Angkor): first results and future prospects. Environmental Geology Special Issue, doi 10.10007/s00254-008-1408-8.CrossRefGoogle Scholar
Aoki, H. and Matsukura, N. (2007). A new technique for non-destructive field measurement of rock-surface strength: an application of the Equotip hardness tester to weathering studies. Earth Surface Processes and Landforms, 32, 1759–1769.CrossRefGoogle Scholar
Arnold, A. and Zehnder, K. (1988). Decay of stony materials by salts in humid atmosphere. In Proceedings 7th International Congress on the Deterioration and Conservation of Stone, pp. 138–148.Google Scholar
Bani-Hani, K. and Barakat, S. (2006). Analytical evaluation of repair and strengthening measures of Qasr al-Bint historical monument. Petra, Jordan. Engineering Structures, 28, 1355–1366.CrossRefGoogle Scholar
Bityukova, L. (2006). Air pollution effect on the decay of carbonate building stones in old town of Tallinn. Water, Air and Soil Pollution, 172, 239–271.CrossRefGoogle Scholar
Borrelli, L., Greco, R. and Gullà, G. (2007). Weathering grade of rock masses as a predisposing factor to slope instabilities: reconnaissance and control procedures. Geomorphology, 87, 158–175.CrossRefGoogle Scholar
,Botswana Roads Department (2001). The Prevention and Repair of Salt Damage to Roads and Runways. Ministry of Works, Transport and Communications, Gaborone, Botswana, ISBN 99912–0–380-X.Google Scholar
Brimblecombe, P. and Camuffo, D. (2003). Long term damage to the built environment. In Brimblecombe, P. (ed.), The Effects of Air Pollution on the Built Environment. London: Imperial College Press, pp. 1–30.CrossRefGoogle Scholar
Brimblecombe, P. and Grossi, C. M. (2008). Millennium-long recession of limestone facades in London. Environmental Geology Special Issue, doi 10.10007/s00254-008-1465-z.CrossRefGoogle Scholar
Brimblecombe, P., Grossi, C. M. and Harris, I. (2006). The effect of long-term trends in dampness on historic buildings. Weather, 61, 278–281.CrossRefGoogle Scholar
Camuffo, D. (1993). Controlling the aeolian erosion of the Great Sphinx. Studies in Conservation, 38, 198–205.CrossRefGoogle Scholar
Chakrabati, B., Yates, T. and Lewry, A. (1996). Effect of fire damage on natural stonework in buildings. Construction and Building Materials, 10, 539–544.CrossRefGoogle Scholar
Charola, A. E., Pühringer, J. and Steiger, M. (2007). Gypsum: a review of its role in the deterioration of building materials. Environmental Geology, 52, 339–352.CrossRefGoogle Scholar
Dang, Z., Liu, C. and Haigh, M. J. (2002). Mobility of heavy metals associated with the natural weathering of coal mine spoils. Environmental Pollution, 118, 419–426.CrossRefGoogle ScholarPubMed
Davidson, C. I., Tang, W., Finger, S.et al. (2000). Soiling patterns on a tall limestone building: changes over 60 years. Environmental Science and Technology, 34, 560–565.CrossRefGoogle Scholar
Dionisio, A. (2007). Stone decay induced by fire on historic buildings: the case of the cloister of Lisbon Cathedral, Portugal. In Prikryl, R. and Smith, B. J. (eds.), Building Stone Decay: From Diagnosis to Conservation. Geological Society of London Special Publication 271, pp. 87–98.Google Scholar
Durgin, P. B. (1977). Landslides and the weathering of granitic rocks. Geological Society of America Reviews in Engineering Geology, III, 127–131.Google Scholar
Farmer, M. F. (1939). Lightning spalling. American Antiquity, 4, 346–348.CrossRefGoogle Scholar
Fassina, V., Favaro, M. and Naccari, A. (2002) Principal decay patterns on Venetian monuments. In Siegesmund, S., Weiss, T. and Vollbrecht, A. (eds.), Natural Stone, Weathering Phenomena, Conservation Strategies and Case Studies. Geological Society of London Special Publication 205, pp. 381–391.Google Scholar
Fitzner, B. and Heinrichs, K. (1991). Weathering forms and rock characteristics of historical monuments carved from bedrock in Petra/Jordan. In Baer, N. S., Sabbioni, C. and Sors, A. I. (eds.), Science, Technology and European Cultural Heritage. Oxford: Butterworth-Heinemann, pp. 908–911.CrossRefGoogle Scholar
Fitzner, B. and Heinrichs, K. (1994). Damage diagnosis at monuments carved from bedrock in Petra, Jordan. In Fassina, V., Ott, H. and Zezza, F. (eds.), Proceedings Third International Conference on the Conservation of Monuments in the Mediterranean Basin, Venice, 22–25 June, 1994, pp. 663–671.
Fitzner, B. and Heinrichs, K. (2002). Damage diagnosis at stone monuments: weathering forms, damage categories and damage indices. In Prikryl, R. and Viles, H. A. (eds.), Understanding and Managing Stone Decay. Prague: The Karolinum Press, pp. 11–56.Google Scholar
Fitzner, B., Heinrichs, K. and Kownatzki, R. (1995). Weathering forms: classification and mapping. In Snethlage, R. (ed.), Fortdruck ans Denkmalpflege und Naturwissenschaft Natursteinkonservierung 1. Berlin: Ernst und Sohn, pp. 41–88 (in German and English).Google Scholar
Fodde, E. (2007). Fired brick and sulphate attack: the case of Moenjodaro, Pakistan. Journal of Architectural Conservation, 13, 69–80.CrossRefGoogle Scholar
Gauri, K. L., Sinai, J. J. and Bandyopadhyay, J. K. (1995). Geologic weathering and its implications on the age of the Sphinx. Geoarchaeology, 10, 119–133.CrossRefGoogle Scholar
Gomez-Heras, M., Buergo, Alvarez M., Fort, R.et al. (2006). Evolution of porosity in Hungarian building stones after simulated burning. In Fort, R., Buergo, M. Alvarez, Gomez-Heras, M. and Vazquez-Calvo, C. (eds.), Heritage, Weathering and Conservation. London: Taylor & Francis, pp. 513–519.Google Scholar
Gomez-Heras, M., Smith, B. J. and Viles, H. A. (2008). Laboratory modelling of gypsum crust growth on limestone related to soot pollution and gaseous sulphur: implications of ‘cleaner’ environments for stone decay. In Lucaszewicz, J. W. and Niemcewicz, P. (eds.), Proceedings, 11th International Congress on Deterioration and Conservation of Stone, Torun. Torun: Nicolaus Copernicus University Press, pp. 105–112.Google Scholar
Goudie, A. S. (2006). The Human Impact on the Natural Environment, 6th edition. Oxford: Blackwell.Google Scholar
Goudie, A. S. and Viles, H. A. (1997). Salt Weathering Hazard. Chichester: Wiley.Google Scholar
Goudie, A. S. and Viles, H. A. (2000). The thermal degradation of marble. Acta Universitatis Carolinae 2000 Geographica, 35, Supplement, 7–16.Google Scholar
Goudie, A. S., Allison, R. J. and McLaren, S. J. (1992). The relations between modulus of elasticity and temperature in the context of the experimental simulation of rock weathering by fire. Earth Surface Processes and Landforms, 17, 605–615.CrossRefGoogle Scholar
Grossi, C. M. and Brimblecombe, P. (2002). The effect of atmospheric pollution on building materials. Journal of Physics IV France, 12, 197–210.CrossRefGoogle Scholar
Gullà, G., Mandaglio, M. C. and Moraci, N. (2006). Effect of weathering on the compressibility and shear strength of a natural clay. Canadian Geotechnical Journal, 43, 618–625.CrossRefGoogle Scholar
Hajpál, M. and Török, A. (2004). Mineralogical and colour changes of quartz sandstones by heat. Environmental Geology, 46, 311–322.CrossRefGoogle Scholar
Hall, K. J. and Walton, D. W. H. (1992). Rock weathering, soil development and colonization under a changing climate. Philosophical Transactions Royal Society of London, B, 338, 269–277.CrossRefGoogle Scholar
Heinrichs, K. (2008). Diagnosis of weathering damage on rock-cut monuments in Petra, Jordan. Environmental Geology, 56, 643–675.CrossRefGoogle Scholar
Hoke, G. D. and Turcotte, D. L. (2004). The weathering of stones due to dissolution. Environmental Geology, 46, 305–10.CrossRefGoogle Scholar
Horta, J. C., O. S. (1985). Salt heaving in the Sahara. Géotechnique, 35, 329–337.CrossRefGoogle Scholar
Howard, K. W. F. and Beck, P. J. (1993). Hydrogeochemical implications of groundwater contamination by road de-icing chemicals. Journal of Contaminant Hydrology, 12, 245–268.CrossRefGoogle Scholar
Islam, M. R., Lahermo, P., Salminen, R., Rojstaczer, S. and Peuraniemi, V. (2000). Lake and reservoir water quality affected by metals leaching from tropical soils, Bangladesh. Environmental Geology, 39, 1083–1089.CrossRefGoogle Scholar
Jaboyedoff, M.Baillifard, F., Bardou, E. and Girod, F. (2004). The effect of weathering on Alpine rock instability. Quarterly Journal of Engineering Geology and Hydrogeology, 37, 95–103.CrossRefGoogle Scholar
Januszke, R. M. and Booth, E. H. S. (1984). Soluble salt damage to sprayed seals on the Stuart Highway. Australian Road Research Board Proceedings, 12(3), 18–31.Google Scholar
Jones, D. K. C. (1980). British applied geomorphology: an appraisal. Zeitschrift für Geomorphologie. N. F., Suppl.-Bd., 36, 48–73.Google Scholar
Kamh, G. M. E., Kallash, A. and Azzam, R. (2008). Factors controlling building susceptibility to earthquakes: 14-year recordings of Islamic archaeological sites in Old Cairo, Egypt: a case study. Environmental Geology Special Issue, doi 10.10007/s00254-007-1162-3.CrossRefGoogle Scholar
Keatings, K., Tassie, G. J., Flower, R. J.et al. (2007). An examination of groundwater within the Hawara Pyramid, Egypt. Geoarchaeology, 22, 533–554.CrossRefGoogle Scholar
Khoury, G. A. (2000). Effect of fire on concrete and concrete structures. Progress in Structural and Engineering Materials, 2, 429–447.CrossRefGoogle Scholar
Khoury, G. A. (2006). Tunnel concretes under fire: Part 1, Explosive spalling. Concrete, November 2006, 62–65.Google Scholar
Laue, S., Bläuer Böhm, C. and Jeannette, D. (1996). Salt weathering and porosity: examples from the crypt of St. Maria im Kapitol, Cologne. Proceedings 8th International Congress on Deterioration and Conservation of Stone, pp. 513–522.Google Scholar
Leduc, C., Favreau, G. and Schoreter, P. (2001). Long term rise in a Sahelian water-table: the continental terminal in south-west Niger. Journal of Hydrology, 243, 43–54.CrossRefGoogle Scholar
Littmann, K., Sasse, H. R., Wagener, S. and Hocker, H. (1993). Development of polymers for the consolidation of natural stone. In Theil, M. J. (ed.), Conservation of Stone and Other Materials. London: Spon, pp. 689–696.Google Scholar
Livingston, R. A. (1989). The geological origins of the Great Sphinx and implications for its preservation. Abstract of paper presented to International Geological Congress, Washington D.C., July 9–19, 1989.
Lohuizen-de Leeuw, J. E. (1973). Moenjo Daro: a cause of common concern. South Asian Archaeology 1973, Leiden: Brill, pp. 1–11.Google Scholar
Mallett, G. P. (1994). Repair of Concrete Bridges. London: Thomas Telford.Google Scholar
Malm, W. C., Schichtel, B. A., Ames, R. B. and Gebhart, K. A. (2002). A 10-year spatial and temporal trend of sulfate across the United States. Journal of Geophysical Research, 107(D22), article no. 4627.CrossRefGoogle Scholar
,Master Plan (1972). Master Plan for the Preservation of Moenjodaro. Department of Archaeology and Museums, Ministry of Education and Provincial Coordination, Government of Pakistan.
Matsuoka, N. and Sakai, H. (1999). Rockfall activity from an alpine cliff during thawing periods. Geomorphology, 28, 309–328.CrossRefGoogle Scholar
McCabe, S., Smith, B. J. and Warke, P. A. (2007). Sandstone response to salt weathering following simulated fire damage: a comparison of the effects of furnace heating and fire. Earth Surface Processes and Landforms, 32, 1874–1883.CrossRefGoogle Scholar
Paradise, T. (2005). Sandstone weathering and aspect in Petra, Jordan. Zeitschrift für Geomorphologie, 46, 1–17.Google Scholar
Price, C. and Brimblecombe, P. (1994). Preventing salt damage in porous materials. In Preventive Conservation. London: International Institute for Conservation of Historic and Artistic Works, pp. 90–93.Google Scholar
Rayleigh, A. (1934). The bending of marble. Proceedings of the Royal Society of London, 144A, 266–279.CrossRefGoogle Scholar
Rhoades, J. D. (1990). Soil salinity: causes and controls. In Goudie, A. S. (ed.), Techniques for Desert Reclamation. Chichester: Wiley, pp. 109–134.Google Scholar
Rosenholtz, J. L. and Smith, D. T. (1949). Linear thermal expansion of calcite, var. Iceland Spar and Yule Marble. American Mineralogist, 34, 846–854.Google Scholar
Royer-Carfagni, G. F. (1999). On the thermal degradation of marble. International Journal of Rock Mechanics and Mining Sciences, 36, 119–126.CrossRefGoogle Scholar
Rozanov, B. G., Targulian, V. and Orlov, D. S. (1991). Soils. In Turner, B. L. (ed.), The Earth as Transformed by Human Action. Cambridge: Cambridge University Press.Google Scholar
Sabbioni, C. (2003). Mechanisms of air pollution damage to stone. In Brimblecombe, P. (ed.), The Effects of Air Pollution on the Built Environment. London: Imperial College Press, pp. 63–106.CrossRefGoogle Scholar
Sabbioni, C., Ghedini, N. and Bonazza, A. (1999). Organic anions in damage layers on monuments and buildings. Atmospheric Environment, 37, 1261–1269.CrossRefGoogle Scholar
Sass, O. and Viles, H. A. (2006). How wet are these walls? Testing a novel technique for measuring moisture in ruined walls. Journal of Cultural Heritage, 7, 257–263.CrossRefGoogle Scholar
Saxena, V. K. and Ahmed, S. (2001). Dissolution of fluoride in groundwater: water-rock interaction study. Environmental Geology, 40, 1084–1087.Google Scholar
Schiavon, N. (2007). Kaolinisation of granite in an urban environment. Environmental Geology, 52, 399–407.CrossRefGoogle Scholar
Scott, W. S. and Wylie, N. P. (1980). The environmental effects of snow dumping: a literature review. Journal of Environmental Management, 10, 219–240.Google Scholar
Seaward, M. R. D. (1997). Major impacts made by lichens in biodeterioration processes. International Journal of Biodeterioration and Biodegradation, 40, 269–273.CrossRefGoogle Scholar
Selwitz, C. (1990). Deterioration of the Great Sphinx: an assessment of the literature. Antiquity, 64, 853–859.CrossRefGoogle Scholar
Seto, S., Nakamura, A., Noguchi, I.et al. (2002). Annual and seasonal trends in chemical composition of precipitation in Japan during 1989–1998. Atmospheric Environment, 31, 3505–3517.CrossRefGoogle Scholar
Shehata, W. M. and Amin, A. A. (1997). Geotechnical hazards associated with desert environment. Natural Hazards, 16, 81–95.CrossRefGoogle Scholar
Shehata, W. and Lotfi, H. (1993). Preconstruction solution for groundwater rise in Sabkha. Bulletin of the International Association of Engineering Geology, 47, 145–150.CrossRefGoogle Scholar
Simao, J., Ruiz-Agudo, E. and Rodriguez-Navarro, C. (2006). Effects of particulate matter from gasoline and diesel vehicle exhaust systems on silicate stones sulfation. Atmospheric Environment, 40, 6905–6917.CrossRefGoogle Scholar
Sippel, J., Siegesmund, S., Weiss, T., Nitsch, K.-H. and Korzen, M. (2007). Decay of natural stones caused by fire damage. In Prikryl, R. and Smith, B. J. (eds.), Building Stone Decay: From Diagnosis to Conservation. Geological Society of London Special Publication 271, pp. 139–151.Google Scholar
Smith, A. G. and Pells, P. J. N. (2008). Impact of fire on tunnels in Hawkesbury Sandstone. Tunnelling and Underground Space Technology, 23, 65–74.CrossRefGoogle Scholar
Smith, A. G. and Pells, P. J. N. (2009). Discussion of the paper ‘Impact of fire on tunnels in Hawkesbury Sandstone’ by Smith and Pells. Tunnelling and Underground Space Technology, 24, 112–114.CrossRefGoogle Scholar
Smith, B. J. and Viles, H. A. (2006). Rapid, catastrophic decay of building limestones: an overview of causes, effects and consequences. In Fort, R., Buergo, M. Alvarez, Gomez-Heras, M. and Vazquez-Calvo, C. (eds.), Heritage, Weathering and Conservation, London: Taylor & Francis, pp. 191–197.Google Scholar
Smith, B. J., Warke, P. A. and Curran, J. M. (2004). Implications of climate change and increased ‘time of wetness’ for the soiling and decay of sandstone structures in Belfast, Northern Ireland. In Prikryl, R., (ed.), Dimension Stone 2004. Leiden: A. A. Balkema, pp. 9–14.Google Scholar
Smith, S. E. (1986). An assessment of structural deterioration on ancient Egyptian monuments and tombs in Thebes. Journal of Field Archaeology, 13, 503–510.Google Scholar
Smith, S. J., Pitcher, H. and Wigley, T. M. L. (2001). Global and regional anthropogenic sulfur dioxide emissions. Global and Planetary Change, 29, 99–119.CrossRefGoogle Scholar
Steiger, M. and Zeunert, A. (1996). Crystallization properties of salt mixtures: comparison of experimental results and models calculations. Proceedings 8th International Congress on Deterioration and Conservation of Stone, pp. 535–544.Google Scholar
Stohrmeyer, P. (2004). Weathering of soapstone in a historical perspective. Materials Characterization, 53, 191–207.Google Scholar
Thomachot, C., Matsuoka, N., Kuchitsu, N. and Morii, M. (2005). Frost damage of bricks composing a railway tunnel monument in Central Japan: field monitoring and laboratory simulation. Natural Hazards and Earth System Sciences, 5, 465–476.CrossRefGoogle Scholar
Thoms, A. V. (2007). Fire-cracked rock features on sandy landforms in the Northern Rocky Mountains: toward establishing reliable frames of reference for assessing site integrity. Geoarchaeology, 22, 477–510.CrossRefGoogle Scholar
Thornbush, M. J. and Viles, H. A. (2006a). Changing patterns of soiling and microbial growth on building stone in Oxford, England after implementation of a major traffic scheme. Science of the Total Environment, 367, 203–211.CrossRefGoogle Scholar
Thornbush, M. J. and Viles, H. A. (2006b). Use of portable X-ray fluorescence for monitoring elemental concentrations in surface units on roadside stone at Worcester College, Oxford. In Fort, R., Buergo, M. Alvarez, Gomez-Heras, M. and Vazquez-Calvo, C. (eds.), Heritage, Weathering and Conservation. London: Taylor & Francis, pp. 613–620.Google Scholar
Torok, A. (2002). Oolitic limestone in a polluted atmospheric environment in Budapest: weathering phenomena and alterations in physical properties. In Siegesmund, S., Weiss, T. and Vollbrecht, A. (eds.), Natural Stone, Weathering Phenomena, Conservation Strategies and Case Studies. Geological Society of London Special Publication 205, pp. 363–379.Google Scholar
Torok, A., Siegesmund, S., Muller, C.et al. (2007). Differences in texture, physical properties and microbiology of weathering crust and host rock: a case study of the porous limestone of Budapest (Hungary). In Prikryl, R. and Smith, B. J. (eds.), Building Stone Decay: From Diagnosis to Conservation. Geological Society of London Special Publication 271, pp. 261–276.Google Scholar
Tratebas, A. M., Cerveny, N. V. and Dorn, R. I. (2004). The effects of fire on rock art: microscopic evidence reveals the importance of weathering rinds. Physical Geography, 25, 313–333.CrossRefGoogle Scholar
Uchida, E., Ogawa, Y., Maeda, N. and Nakagawa, T. (1999). Deterioration of stone materials in the Angkor monuments, Cambodia. Engineering Geology, 55, 101–112.CrossRefGoogle Scholar
Vassie, P. (1984). Reinforcement corrosion and the durability of concrete bridges. Proceedings of the Institution of Civil Engineers, 76, 713–723.CrossRefGoogle Scholar
Viles, H. A (1994). Time and Grime. School of Geography, University of Oxford Research Paper No. 50.Google Scholar
Viles, H. A. (2002). Implications of future climate change for stone deterioration. In Siegesmund, S., Weiss, T. and Vollbrecht, A. (eds.), Natural Stone, Weathering Phenomena, Conservation Strategies and Case Studies. Geological Society of London Special Publication 205, 407–418.CrossRef
Viles, H. A. and Gorbushina, A. A. (2003). Soiling and microbial colonisation on urban roadside limestone: a three year study in Oxford, England. Building and Environment, 38, 1217–1224.CrossRefGoogle Scholar
Wang, K. (2006). Damaging effects of deicing chemicals on concrete materials. Cement and Concrete Composites, 28, 173–188.CrossRefGoogle Scholar
Webster, A. and May, E. (2006). Bioremediation of weathered building stone surfaces. Trends in Biotechnology, 24, 255–260.CrossRefGoogle ScholarPubMed
Wedekind, W. and Ruedrich, J. (2006). Salt-weathering, conservation techniques and strategies to protect the rock cut façades in Petra/Jordan. In Fort, R., Buergo, M. Alvarez, Gomez-Heras, M. and Vazquez-Calvo, C. (eds.), Heritage, Weathering and Conservation. London: Taylor & Francis, pp. 261–267.Google Scholar
Widhalm, C., Tschegg, E. and Eppensteiner, W. (1996). Anisotrophic thermal expansion causes deformation of marble claddings. Journal of Performance of Constructed Facilities, 10, 5–10.CrossRefGoogle Scholar
Widhalm, C., Tschegg, E. and Eppensteiner, W. (1997). Acoustic emission and anisotropic expansion when heating marble. Journal of Performance of Constructed Facilities, 11, 35–40.CrossRefGoogle Scholar
Wilson, J. F. (2003). Lightning-induced fracture of masonry and rock. International Journal of Solids and Structures, 40, 5305–5318.CrossRefGoogle Scholar
Wüst, R. A. J. and Schlüchter, C. (2000). The origin of soluble salts in rocks of the Thebes Mountains, Egypt: the damage potential to ancient Egyptian wall art. Journal of Archaeological Science, 27, 1161–1172.CrossRefGoogle Scholar
Zador, M. (1992). Experience with cleaning and consolidating stone facades in Hungary. In Webster, R. G. M. (ed.), Stone Cleaning and the Nature, Soiling and Decay Mechanisms of Stone. London: Donhead, pp. 146–152.Google Scholar

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