Thenardite: Difference between revisions

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== The importance of the heptahydrate in the damage process ==
== The importance of the heptahydrate in the damage process ==
see <bib id="Saidov:2012"/>


== Hydration pressure  ==
== Hydration pressure  ==

Revision as of 09:37, 18 December 2013

Thenardite[1][2]
HJS-Na2SO4-111703-02-10x.jpg
Mineralogical name Thenardite
Chemical name Sodium sulfate
Trivial name Pyrotechnite
Chemical formula Na2SO4
Other forms Mirabilite (Na2SO4•10H2O)
Sodium sulfate heptahydrate (Na2SO4•7H2O)
Crystal system orthorhombic
Crystal structure
Deliquescence humidity 20°C 81.7% (25°C)
Solubility (g/l) at 20°C 162 g/l
Density (g/cm³) 2.689 g/cm³
Molar volume 53.11 cm3/mol
Molar weight 142.04 g/mol
Transparency transparent to translucent
Cleavage perfect
Crystal habit
Twinning
Phase transition
Chemical behavior
Comments soluble in water and glycerin,
not soluble in pure alcohol
Crystal Optics
Refractive Indices nx = 1.468
ny = 1.473
nz = 1.483
Birefringence Δ = 0.015
Optical Orientation positive
Pleochroism
Dispersion
Used Literature
{{{Literature}}}


Authors: Hans-Jürgen Schwarz , Michael Steiger, Tim Müller
English translation by Matthieu Angeli
back to Sulfate

Sodium sulfate and thenardite[edit]

Abstract[edit]

Sodium sulfate and its phases thenardite, mirabilite and heptahydrate are described. Heptahydrate´s role as a major source of damage is also explained .

Occurrence[edit]

Both thenardite and mirabilite occur as natural minerals. In nature sodium sulfate occurs in mineral waters in the form of double salts, as deposits of former salt lakes. The hydrated sodium sulfate was first described by Glauber in 1658 where he called it "sal mirabilis". Mirabilite is also known as "Glauber's salt" in honor of its discoverer.

Origin and formation of thenardite / mirabilite in monuments[edit]

When sodium ions in conjunction with other anions enter porous inorganic building materials, sodium sulfate may be formed by reaction with sulfate contributed by other sources, for example air contaminated with sulfur oxide gases. Portland cement contains a certain amount of sodium or potassium sulfate. In Germany, the standardization institute (DIN) allows a content of up to 0.5 % soluble alkalis. This means that 100 kg of Portland cement containing only 0.1% soluble Na2O can form 520g of Mirabilite when reacting with sulfate [calculation by Arnold/Zehnder 1991]. Sodium ions can also enter into monuments from various cleaning materials and, in older restoration products, such as water glass. Ground water, and even surface water, are also a possible source of Na+-ions as well as sulfate ions. De-icing road salt may contain a large amount of soluble sodium chloride. Finally, in coastal areas, sea water is a significant source of NaCl.

Solubility behavior[edit]

Figure1: Solubility of Na2SO4 in water, Graph: M. Steiger


The structures of both thenardite and mirabilite belong to the group of easily soluble salts and therefore they are easily mobilized (see table hygroscopicity of the salts and their equilibrium RH). The solubility of sodium sulfate is highly dependent on temperature. For this reason, a rapid drop of temperature is highly likely to yield very high supersaturation and salt crystallization.

Hygroscopicity[edit]

Figure2:Deliquescence of Na2SO4, Graph: M. Steiger

The temperature effect on the deliquescence points of thenardite and mirabilite is shown below. The striking features here are the opposite curve transitions. In the presence of other ions (in salt mixtures), the parameters of the equilibrium moisture content, as well as the necessary temperature and humidity conditions for recrystallization, change significantly. The following table shows experimental data of equilibrium moisture for different salt mixtures at different temperatures.It turns out that all the values of equilibrium moisture content are lower than those of the pure salt mirabilite (see table equilibrium moisture content as a function of temperature).


Table 1 - Information about the equilibrium moisture of saturated solid solutions (mixing ratio: saturated sol.A / saturated sol.B = 1:1) [Vogt.etal:1993]Title: Der Einfluss hygroskopischer Salze auf die Gleichgewichtsfeuchte und Trocknung anorganischer Baustoffe
Author: Vogt, R.; Goretzki, Lothar
Link to Google Scholar
MgSO4 Ca(NO3)2 KNO3
Na2SO4 • 10H2O 87(21°C) 74 (21°C) 81(21°C)


Water vapor sorption:

Figure 3: Deliquescence points of pure salts thenardite and mirabilite [Arnold.etal:1991]Title: Monitoring Wall Paintings Affected by soluble Salts
Author: Arnold, Andreas; Zehnder, Konrad
Link to Google Scholar

The table below shows additional information for estimating the hygroscopicity of sodium sulfate for the sorption behavior of pure salt and the mixture with halite at different relative humidity levels:


Table 2: Moist sorption of sodium sulphate in M.% after 56 days of storage [after [Vogt.etal:1993]Title: Der Einfluss hygroskopischer Salze auf die Gleichgewichtsfeuchte und Trocknung anorganischer Baustoffe
Author: Vogt, R.; Goretzki, Lothar
Link to Google Scholar
]
Air humidity 87% r.F. 81% r.F. 79% r.F.
Na2SO4 79 0 0
Na2SO4+NaCl (1:1 molar mixture) 157 32 15


Hydration behavior[edit]

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Conversion of mirabilite (?) into thenardite

The Na2SO4 – H2O system:

The only stable forms of sodium sulfate are the decahydrate (mirabilite) and the anhydrite (thenardite). The generation of mirabilite by recrystallization of the salt from an aqueous supersaturated solution occurs at 32.4°C. In particular, the transition from thenardite to mirabilite and the incorporation of 10 water molecules in the crystal lattice causes a volume expansion of 320%. This transition happens at a relatively low temperature (32-35°C), the damage caused by this salt is highly dependent on the temperature and thus on the environment. This temperature range is given as a guide, because this transition could happen for example at 25°C at 80% relative humidity, or even at 0°C at 60.7% relative humidity [information from Gmelin]. Due to this strong dependence on the environmental parameters, an estimate of the damage caused on buildings by crystallization and hydration of sodium sulfate are very difficult to obtain.

The importance of the heptahydrate in the damage process[edit]

see [Saidov:2012]Title: Sodium sulfate heptahydrate in weathering phenomena of porous materials
Author: Saidov, Tamerlan Adamovich
Link to Google Scholar

Hydration pressure[edit]

Analytical detection[edit]

Microscopy
[edit]

Laboratory investigation:
Through microscopic observations regarding the solubility behavior, good solubility in water and no solubility in ethanol can be confirmed. Thenardite and mirabilite do not have morphological characteristics that could help identification with the use of simple re-crystallization experiments.

Refractive indices:    nx = 1.468; ny =1,473; nz =1.483
Birefringence:      Δ = 0.015
Crystal class:            orthorhombic


Polarized light microscopy examination:

The raw sampling material and the re-crystallized preparation change their water content, depending on the conditions of relative humidity and temperature. In dry air conditions (RH < 80% and room temperature) mirabilite looses its chemically bound water and changes to thenardite. This process can be clearly understood and reproduced using a microscope, when the process of re-crystallization is observed. Mirabillite does show the characteristic abnormal interference colors. During the moisture loss and the formation of thenardite these abnormal interference colors become weaker.

The refractive index assignment of thenardite is carried out using the immersion method. Due to the low maximum birefringence, thenardite mostly displays gray interference colors. The extinction is parallel or symmetrical.


Possible mistakes:

Generally, the differentiation between certain kinds of sulfates (they are listed below, thenardite included) is a problem without micro-chemical determination of the anions, because the refractive indices of the salts lie very closely together and all salts show a low birefringence. It is best to use an immersion medium with a nD- value of 1,48, thus making the differentiation within this group possible. Moreover, the properties mentioned below can be consulted as criteria for determination. Thenardite is unambiguously, but indirectly determined by re-crystallizing a sample and observing the abnormal interference colors, which occur when mirabiltite is identified in its high hydrate form.

Table 3: Characteristics for differentiating thenardite from other sulfates
Salt phase Characteristic
Boussingaultite (NH4)2Mg(SO)4 • 6H20 no abnormal interference colors/ inclined extinction
Pikromerite K2Mg(SO4)2 • 6H20 no abnormal interference colors/ inclined extinction
Bloedite Na2Mg(SO4)2 • 6H20 all indices >1.48 / no abnormal interference colors/ inclined extinction / optically negative orientation.
Glaserite K3Na(SO4)2 all indizes >1.48 / no abnormal interference colors/ inclined extinction
Arcanite K2SO4 all indices >1.48 / no abnormal interference colors
Magnesium formiate Mg(HCO2)2 • 2H2O comparatively high birefringence / no abnormal interference colors/ inclined extinction


Observation of mixed systems:

The mixed system Na+– Ca2+– SO4 2-: The precipitation of gypsum takes place first during re-crystallization, which is due to its low solubility. The distinct needle like habit of single gypsum crystals and aggregates remains. The precipitation of sodium sulfate takes place later. The actual crystal growth takes place much faster. The morphology is non-specific.

Mixed system Na+– SO4 2-– Cl-: The precipitation of both kinds of particle starts approximately at the same time, halite with its characteristic morphology, sodium sulfate in extremely varying forms.

Pictures of salt and salt damage[edit]

In the field[edit]

Under the polarizing microscope[edit]


Weblinks
[edit]

Literature[edit]

[Sperling.etal:1980]Sperling, C.H.B.and Cooke, R.U. (1980): Salt Weathering on Arid Environment, I. Theoretical ConsiderationsII. Laboratory Studies. In: Papers in Geography, 8 ()Link to Google Scholar
[Steiger.etal:2008]Steiger, Michael; Asmussen, Sönke (2008): Crystallization of sodium sulfate phases in porous materials: The phase diagram Na2SO4–H2O and the generation of stress. In: Geochimica et Cosmochimica Acta, 72 (17), 4291-4306, UrlLink to Google Scholar
[Vogt.etal:1993]Vogt, R.; Goretzki, Lothar (1993): Der Einfluss hygroskopischer Salze auf die Gleichgewichtsfeuchte und Trocknung anorganischer Baustoffe, unveröffentlichter Bericht.Link to Google Scholar
[Winkler.etal:1970]Winkler, Erhard M.; Wilhelm, E.J. (1970): Saltburst by Hydration Pressure in Architectural Stone in Urban Atmosphere. In: Geological Society of America, Bulletin, 81 (), 567-572Link to Google Scholar
[Winkler:1975] Winkler, Erhard M. (1975): Stone: Properties, Durability in Man´s Environment, Springer Verlag, WienLink to Google Scholar