Talk:Epsomite: Difference between revisions

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The allocation of the refractive indices of epsomite, is carried out according to the immersion method (successively by means of embedding media n<sub>D</sub>=1,518; n<sub>D</sub>=1,47; n<sub>D</sub>=1,46). When using an immersion medium with a refractive index of  n<sub>D</sub>=1,45 on many single particles a slight but distinct variation in relief is visible at rotation. Because epsomite belongs to the class of orthorhombic crystals, it never appears in an oblique but always in a parallel symmetrical extinction. Beside epsomite, hexahydrite often forms, which is monoclinic and has nearly identical refractive indices. A distinction between these two hydrate stages of magnesium sulfate is only possible through the allocation of the crystal class. Due to the low path difference epsomite crystals usually only show low inference colors in the range of the first order.  
The allocation of epsomite to the refractive indices is carried out according to the immersion method (successively by means of embedding media n<sub>D</sub>=1,518; n<sub>D</sub>=1,47; n<sub>D</sub>=1,46). When using an immersion medium with a refractive index of  n<sub>D</sub>=1,45 on many single particles a slight but distinct variation in relief is visible at rotation. Because epsomite belongs to the class of orthorhombic crystals, it never appears in an oblique but always in a parallel symmetrical extinction. Beside epsomite, hexahydrite often forms, which is monoclinic and has nearly identical refractive indices. A distinction between these two hydrate stages of magnesium sulfate is only possible through the allocation of the crystal class. Due to the low path difference epsomite crystals usually only show low inference colors in the range of the first order.  


'''Possibility for mistakes:'''<br>  
'''Possibility for mistakes:'''<br>  

Revision as of 12:02, 28 January 2012

Epsomite[1][2]
HJS MgSO4 092503-2.jpg
Mineralogical name Epsomite
Chemical name Magnesium sulfate heptahydrate
Trivial name Bitter Salts, reichardtite, seelandite
Chemical formula MgSO4•7H2O
Other forms Kieserite (MgSO4•H2O)
Sanderite (MgSO4•2H2O)
Starkeyite (MgSO4•4H2O)
Pentahydrite(MgSO4•5H2O)
Hexahydrite (MgSO4•6H2O)
Meridianite (MgSO4•11H2O)
Magnesium 12-Hydrate
Crystal system orthorhombic
Crystal structure
Deliquescence humidity 20°C 90.1% (20°C), 94% (30°C)
Solubility (g/l) at 20°C 710 g/l
Density (g/cm³) 146.8 cm3/mol
Molar volume {{{MolVolume}}}
Molar weight 1.67 g/cm3
Transparency transparent to translucent
Cleavage clear to perfect
Crystal habit small, acicular, fibre like crystals, granular agregates, crusts
Twinning rare
Phase transition
Chemical behavior
Comments can be produced from an aqueous solution under 50°C
Crystal Optics
Refractive Indices nx = 1.433
ny = 1.455
nz = 1.461
Birefringence Δ = 0.028
Optical Orientation biaxial negative
Pleochroism none
Dispersion
Used Literature
{{{Literature}}}


<bibimport/> Authors: Hans-Jürgen Schwarz, Tim Müller, Nils Mainusch
back to Sulfate

Introduction[edit]

Occurrenceof epsomite[edit]

The natural mineral epsomite was first extracted in 1695, from the mineral waters near Epsom (London), where the mineral name was derived from. Just as kieserite (magnesium sulfate mono hydrate), single crystals rarely occur in nature. Both magnesium salts, as well as their hydrate forms are extracted from alpine deposits and occur together with sylvine and rock salt in north Germany, and in the top layer of salt deposits by Staßfurt (near Magdeburg).

Information on the origin and formation of epsomite on monuments[edit]

The formation of magnesium sulfate on monuments requires the presence of soluble magnesium compounds, and magnesium ions. Different building materials on historic structures can contain magnesium compounds. Some examples are listed below:

  • Utilization of lime with dolomite components: Dolomite (CaMg(CO3)2 ) is a double salt. If lime stone containing dolomite components is heated, slaked and used as mortar, CaCO3 and MgCO3·xH20 form through this process (e.g. Nesquehonit MgCO3·3H20 including the molecules from the water of crystallization). The water solubility of MgCO3·3H20 at 1,76 g/l, is significantly above the solubility of calcite (0,014 g/l) and dolomite (0,078 g/l). If magnesium ions have been dissolved by moisture, they can form several different magnesium salts in the presents of the corresponding anions. The formation of magnesium sulfate can occur if, in connection with dolomite containing plasters, gypsum was used for stucco or plaster, readily supplying sulfates.
  • Utilization of magnesia containing binder: Magnesia binder consists essentially of MgO and MgCl2 or magnesium sulfate. The fully cured and solidified binder can contain highly hygroscopic magnesium salts, which can be converted to magnesium sulfate.
  • Utilization of cement: According to the German standard, DIN 1164 [DIN1164:1994]Title: DIN 1164-1: Zement Teil 1, Zusammensetzung und Anforderungen
    Author: DIN
    Link to Google Scholar
    a maximum content MgO of 5 M.% is tolerated in cements. Apart from the possibility of causing damage by delayed quenching, due to the expansion of the magnesia, magnesium ions can theoretically be released and cause the formation of magnesium sulfate.

Deicing salt can be another source of magnesium sulfate, it often contains a small proportion of readily soluble MgCl2. Furthermore, the magnesium supply can occur through constant soil leaching in connection with rising damp.


Solubility properties[edit]

>Figure 1: Solubility of MgSO4 in water (Diagram: Michael Steiger)
Figure 2: Darstellung der temperaturabhängigen Veränderung der Löslichkeit von Epsomit im Vergleich mit anderen Salzphasen (nach [Stark.etal:1996]Title: Bauschädliche Salze
Author: Stark, Jochen; Stürmer, Sylvia
Link to Google Scholar
)

The solubility of the above magnesium sulfate forms is significantly above 100 g/l (bei 20°C), and they are part of the group of readily soluble salts. In principle, this makes for a great mobility of the salt and frequent shifting of the accumulation zones inside the material fabric. Due to the influence of temperature on solubility, there is a risk of precipitation of the dissolved salts in combination with rapid temperature drops. -->

Hygroscopicity[edit]

The low hygroscopicity of the pure salt epsomite which becomes evident in the high value of the equilibrium moisture content in the range of 88-90% RH, cannot be considered in isolation. In mixed systems, i.e. under the influence of foreign ions the sorption point is lower (see table). The possibility of hygroscopic moisture uptake with the connected difficulties is still possible despite the high Deliquescence point.
-->

Figure 1: The system MgSO4/H2 form -30°C to 80°C , (Diagram: Michael Steiger)


Table 1:Deliquescence points at different temperatures [after [Arnold.etal:1991]Title: Monitoring Wall Paintings Affected by soluble Salts
Author: Arnold, Andreas; Zehnder, Konrad
Link to Google Scholar
]
10°C 20°C 25°C 30°C
86,9% r.F. 90,1% r.F. 88,3% r.F. 88,0% r.F.


Sorption of moisture[edit]

Tabele 2: Behavior concerning moisture sorption of magnesium sulfate [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
]
Moisture sorption at 87%r.F. 81%r.F. 70%r.F. 61%r.F. 50%r.F.
MgSO4 76 75 70 71 27
MgSO4 + NaCl
(1:1 molare mixture)
240 146 75 50 20


Crystallization pressure[edit]

Due to the high solubility of the salt, dissolving and recrystallization processes take place under the appropriate humidity conditions. In theory the occurring crystallization pressure can be calculated and ranges between 10,5-12,5 N/mm2 for epsomite and between 11,8- 14,1 N/mm2 for hexahydrite. Compared to other damaging salts these values are thus to be found in the lower third of a calculated scale of values, alltogether ranging from 7,2 bis 65,4 N/mm2 [according to [Winkler:1975]Title: Stone: Properties, Durability in Man´s Environment
Author: Winkler, Erhard M.
Link to Google Scholar
].

Hydration behavior[edit]

The system MgSO4 – H2O: the listed hydrate stages of magnesium sulfates are known to be stable compounds. With the exception of magnesium sulfate- 12- hydrate, all the above stages of the chemically combined water of magnesium sulfate on monuments are visible, but essentially only epsomite, hexahydrite, pentahydrite and kieserite occur.

At room temperature and an RH between 50%-90%, epsomite is the most stable hydrate stage. If the RH drops significantly lower than 50% at room temperature, the chemically combined water is released and lower hydrate stages are formed. Hexahydrite (MgSO4 × 6H2O) as pure salt is only stable at a temperature range of approx. 48°C to 67,5 °C. Pentahydrite has been thought to be metastable or unstable when exposed to the air, nevertheless the existence of these two salt phases has been detected radiographically on building structures. The expulsion of the hydrate water can occur up to the formation of kieserite at elevated temperatures.

Hydration pressure[edit]

Possible variations in magnesium sulfate´s content of chemically combined water on constructions are a fact, and it is likely, that changes in the hydrate stages pentahydrite, hexahydrite and epsomite (subject to climatic fluctuations) are taking place in situ. The addition of a water molecule into the crystal lattice of hexahydrite, resulting in the transformation to epsomite, is associated with an increase in volume of around 10%. At temperatures from 0-20°C and 70% RH the resulting hydration pressure can be specified at values between 6,8 –9,7 N/mm2. The conversion from kieserite to hexahydrite causes an increase in volume of approx. 140% [according to [Stark.etal:1996]Title: Bauschädliche Salze
Author: Stark, Jochen; Stürmer, Sylvia
Link to Google Scholar
].

Conversion reaction[edit]

The following case is a good example for the potential damage connected with the formation of epsomite: if magnesium carbonate (as magnesite) is present in the material structure of a monument, epsomite can form through the influence of sulfuric acid. According to [Stark.etal:1996]Title: Bauschädliche Salze
Author: Stark, Jochen; Stürmer, Sylvia
Link to Google Scholar
this conversion is linked to an increase in volume of over 400%.


Analytical identification[edit]

On objects, crystallized magnesium sulfate can appear in differing morphologies, but specific forms appear more frequently. One examined object displayed a loose crust of an opaque, gray to yellow substance in situ, which was a mixture of epsomite and hexahydrite (part of the thesis by Mainusch [Mainusch:2001]Title: Erstellung einer Materialsammlung zur qualitativen Bestimmung bauschädlicher Salze für Fachleute der Restaurierung
Author: Mainusch, Nils
Link to Google Scholar
). At the monastery church St. Johann at Müstair epsomite appeared as “granular crusts”. Magnesium sulfate efflorescence in the shape of salt whiskers was detected at St. Georgs church in Steiermark (Styria). -->


Micro- chemistry[edit]

-->

Microscopy[edit]

Laboratory examination:

Breathing onto a (predominantly) magnesium sulfate efflorescence, causes no observable macroscopic changes. However, characteristics are: the good solubility in water, a pH of 7, the formation of a ring- shaped slightly raised seam (visible by the naked eye), or a transparent layer that remains in place after the evaporation of the aqueous solvent. In laboratory tests on objects the results should be double checked with the microscope. Observations of the raw sample material and the recrystallized salt, show that magnesium sulfate crystals appear in unspecific forms in sample material. Experiments to produce well- shaped, single magnesium sulfate crystals, by recrystallization in aqueous solution have not been very successful, because of a strong tendency for intergrowth. Usually the previously mentioned, distinct, ring- shaped seam of intergrown crystals forms, when the magnesium sulfate containing solute is evaporated. Epsomite shows a low solubility in anhydrous ethanol and glycerin under the microscope. For further examinations using polarized light microscopy, a considerable difficulty is the creation of good preparations, due to the tendency of magnesium sulfate to form only few equidimensional or elongated single crystals. The low solubility in ethanol, nevertheless allows to isolate single particles by repeatedly adding recrystallized material. Both on the base material as well as the recrystallized product, examination using polarized light microscopy should be carried out.

Refractive indices:  nX = 1,433, ny = 1,455, nz
Birefringence:    Δ = max.  0,028
Crystal class:          orthorhombisch

Polarized light microscopic examination:


The allocation of epsomite to the refractive indices is carried out according to the immersion method (successively by means of embedding media nD=1,518; nD=1,47; nD=1,46). When using an immersion medium with a refractive index of nD=1,45 on many single particles a slight but distinct variation in relief is visible at rotation. Because epsomite belongs to the class of orthorhombic crystals, it never appears in an oblique but always in a parallel symmetrical extinction. Beside epsomite, hexahydrite often forms, which is monoclinic and has nearly identical refractive indices. A distinction between these two hydrate stages of magnesium sulfate is only possible through the allocation of the crystal class. Due to the low path difference epsomite crystals usually only show low inference colors in the range of the first order.

Possibility for mistakes:

Epsomite/hexahydrite are to be allocated, once the examination criteria below have been clarified:

  • good water solubility
  • characteristic appearance at recrystallization 
  • low birefringence


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X- Ray diffraction[edit]

Raman-Spectroscopiy[edit]

DTA / TG[edit]

IR-Spectroscopy[edit]


Umgang mit Epsomitschäden
[edit]

-->

Salts and deteriotion pattern[edit]

On objects[edit]

Under the polarising microscope[edit]


Weblinks[edit]

SLeithaeuser 13:04, 25 January 2012 (CET) in Progress