Immobilization of salts
The so-called "barium" method is based on the fact that when a soluble barium compound is added to a solution containing soluble sulfate salts, the highly insoluble barium sulfate will precipitate out and be 'immobilized' given its extremely low solubility. However, other soluble salts may remain from the counter ions of the original and barium compound added. These, however, may be less damaging.
The above approach is used for the conversion of gypsum , in particular for gypsum efflorescence and crusts, into barium sulfate. It has been in use for several years [Hammer:1996]Title: Salze und Salzbehandlung in der Konservierung von Wandmalerei und Architekturoberfläche.
Author: Hammer, Ivo
and has proven to be effective when used appropriately. The gypsum conversion  is best carried out in five steps [Matteini:1991]Title: In Review: An Assessmant of Florentine Methods of Wall Painting Conservation Based on the Use of Mineral Treatments
Author: Matteini, Mauro
1. Dissolution of gypsum
CaSO4•2H2O + (NH4)2CO3 → (NH4)2SO4 + CaCO3 + 2H2O
The first step is the application of an ammonium carbonate containing poultice to the surface to be treated. This leads to the conversion of the relatively insoluble gypsum into soluble ammonium sulfate that partly migrates into the poultice. The remaining ammonium sulfate will eventually migrate and distribute itself in the material. The reaction will also form calcium carbonate (calcite) and this will have a consolidating effect. However, any calcite forming on the surface has to be removed diligently to avoid its whitening effect. Any excess ammonium carbonate decomposes into gaseous ammonia, carbon dioxide and water. It is to be taken into account that ammonium carbonate may alter decorative mural paintings that contain proteinaceous additives.
2. Precipitation of the insoluble salts
(NH4)2SO4 + Ba(OH)2 → BaSO4↓ + 2NH3+ 2H2O
The second step is the application of a barium hydroxide containing poultice. The soluble ammonium sulfate in the substrate will react to form the highly insoluble barium sulfate. The counter ions, hydroxyl and ammonium will evaporate as ammonia and water.
3. First consolidating reaction
Ba(OH)2 + CO2→ BaCO3↓ + H2O
Any excess barium hydroxide will react with ambient carbon dioxide to form barium carbonate. This has a consolidating effect.
4. The second consolidating reaction
Ba(OH)2 + CaCO3 → BaCO3↓+ Ca(OH)2
There may be an exchange reaction between any existing calcite in the substrate and the barium hydroxide where the outer surface of the calcite grains turn into calcium hydroxide gel while barium carbonate may also accrue on other crystals.
5. Ca(OH)2 + CO2 → CaCO3↓+ H2O
Any calcium hydroxide formed will re-carbonate increasing the consolidating effect. The reactions 4 and 5 have not as yet been thoroughly investigated and require further studies.
IMPORTANT NOTE: The method should not be used in the presence of a high concentration of nitrates or organic binders. This approach does not provide an adhesive effect.
Nitrates will result in the formation of barium nitrate, which is slightly soluble leading to its visible crystallization on the surface. The organic binders in tempera or oil paintings do not tolerate the high alkalinity of barium hydroxide resulting in their hydrolysis or saponification. Matteini [Matteini:1991]Title: In Review: An Assessmant of Florentine Methods of Wall Painting Conservation Based on the Use of Mineral Treatments
Author: Matteini, Mauro
is of the opinion, that in old paintings, these organic binders have largely transformed into inorganic compounds such as calcium oxalate and the above reactions will not necessarily take place, the use of this method can therefore be justified.
Similarly, magnesium sulfate can also be converted into the highly insoluble barium sulfate and ideally turn into the relative insoluble magnesium carbonate, rendering harmless the damaging salt [Friese.etal:1999]Title: Salze im Mauerwerk - Möglichkeiten zur Entsalzung und zur Salzumwandlung
Author: Friese, Peter; Protz, A.
Treatment with lead hexafluorosilicate
In the past, another conversion method based on the use of lead hexafluorosilicate was sometimes recommended when commercial restoration Renders/Mortars, called Sanierputze in German, to prevent salts from migrating into the fresh render. The commercial restoration renders are formulated with a water repellent, mostly Na-oleate (that with the render turns into Ca-oleate) or Zn-stereate. Hydrophobicity of the render will prevent salts from penetrating it, and therefore, it will have a longer service-life. To be taken into account it that these commercial restoration renders were formulated mostly for old farm houses where walls tend to be saturated with salts. The render is applied to both sides so that salts are "trapped" within the wall which will remain moist due to salt hygrocopicity, but the renders will be dry because of their hydrophobicity. Different manufacturers suggest a variety of combinations. The most important ones are produced on the basis of lead hexafluorosilicate. Barium containing agents are also offered.
Even though a certain effectiveness of the treatment has been established, it must be stressed that soluble lead salts are a risk to the workforce and to the environment and should be avoided. For this reason, attempts should be made to achieve the same effect (the prevention of a rapid salt migration into the new plaster) through the use of additives to the render mix to reduce pore sizes and turn it hydrophobic. For this purpose sodium silicate compounds and potassium methyl siliconate/fluate, i.e., salts of hexafluorosilicic acid are usually used. This will reduce salt migration to the surface of the set render. However, there may be some problems when applying the render. As active ingredients Lead hexafluorosilicate reacts with sulfate and chloride compounds in complex reactions, forming a variety of products, which are nearly all hardly soluble or insoluble.
The reaction may be as follows:
Na2SO4 (s) + PbSiF6(s) → PbSO4 (sls)+ Na2SiF6 (sls)
Na2CO3 (s) + PbSiF6 (s) → PbCO3(is) + Na2SiF6 (sls)
MgSO4 (s) + PbSiF6 (s) → PbSO4 (sls) + MgSiF6 (sls)
2NaCl (s) + PbSiF6 (s) → PbCl2 (sls) + Na2SiF6 (sls)
(sls - slightly soluble; s - soluble; is - insoluble)
- http://www.fead-gmbh.de/Naturstein%20Gips.html, gesehen 17.1.2011
- http://www.baufachinformation.de/denkmalpflege.jsp?md=1988017124771, gesehen 17.1.2011
|[Friese.etal:1999]||Friese, Peter; Protz, A. (1999): Salze im Mauerwerk - Möglichkeiten zur Entsalzung und zur Salzumwandlung. In: Venzmer, H. (eds.): Entfeuchtung/Entsalzung 10. Hanseatische Sanierungstage FAS - Schriftenreihe Heft 10, 211-230|
|[Hammer:1996]||Hammer, Ivo (1996): Salze und Salzbehandlung in der Konservierung von Wandmalerei und Architekturoberfläche.. In: Pursche, Jürgen (eds.): Salzschäden an Wandmalereien, Bayerisches Landesamt für Denkmalpflege, 81-106|
|[Matteini:1991]||Matteini, Mauro (1991): In Review: An Assessmant of Florentine Methods of Wall Painting Conservation Based on the Use of Mineral Treatments. In: Cather, Sharon (eds.): The Conservation of Wall Paintings: Proceedings of a symposium organized by the Coutrauld Institut of Art and the Getty Conservation Institute, London, July 13-16, 1987, The Getty Conservation Institute, 137-148|