Halite: Difference between revisions
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=== Laboratory analysis === | === Laboratory analysis === | ||
Sodium chloride crystals can be reliably identified on the basis of morphological features. Individual particles usually form cubic or octahedral shapes and, therefore, clearly display right angles in their crystal construction. <br> | Sodium chloride crystals can be reliably identified on the basis of their morphological features. Individual particles usually form cubic or octahedral shapes and, therefore, clearly display right angles in their crystal construction. <br> | ||
'''Refractive index:''' n<sub>D</sub> = 1.544<br>'''Crystal category:''' cubic<br> | '''Refractive index:''' n<sub>D</sub> = 1.544<br>'''Crystal category:''' cubic<br> | ||
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'''Examination by polarized microscopy:''' | '''Examination by polarized microscopy:''' | ||
There are few salts belonging to the cubic crystal system which can be found in masonry, i.e., sodium chloride (halite), potassium chloride (sylvite) and calcium fluoride (flourite). Only two first salts are highly soluble and therefore they are the ones that can cause damage to the masonry. Because of its isotropic internal structure these salts do not display birefringence. | |||
The classification of the refractive index occurs by immersion method in a standard oil with a refractive index of n<sub>D</sub> =1.518. Halite crystals display the same optical density in every direction so that the speed and orientation of linear polarized light waves are not distorted | The classification of the refractive index occurs by immersion method in a standard oil with a refractive index of n<sub>D</sub> =1.518. Halite crystals display the same optical density in every direction so that the speed and orientation of linear polarized light waves are not distorted, therefore, when viewed between crossed polars, the crystals are not visible, i.e., they are "estinguished". | ||
<br> '''Differentiation of halite from similar salts:'''<br> | <br> '''Differentiation of halite from similar salts:'''<br> | ||
The | The three above mentioned isotropic salts can be easily differentiated. | ||
<br clear="all"> | <br clear="all"> | ||
Revision as of 23:00, 6 December 2013
Authors: Hans-Jürgen Schwarz, Nils Mainusch
English version by Christa Gerdwilker
back to Chloride
| Halite[1][2][3] | |
| |
| Mineralogical name | Halite |
| Chemical name | Sodium chloride |
| Trivial name | Common Salt, Rock Salt |
| Chemical formula | NaCl |
| Other forms | Sodiumchloride Dihydrate/Hydrohalite (NaCl•2H2O)[4] |
| Crystal system | cubic |
| Crystal structure | |
| Deliquescence humidity 20°C | 75.7% (10°C), 75.3% (25°C) |
| Solubility (g/l) at 20°C | 358 g/l |
| Density (g/cm³) | 2.163 g/cm3 |
| Molar volume | 27.02 cm3/mol |
| Molar weight | 58.44 g/mol |
| Transparency | transparent to translucent |
| Cleavage | perfect |
| Crystal habit | cubic crystal, granular, massive aggregates |
| Twinning | none |
| Phase transition | |
| Chemical behavior | |
| Comments | water soluble |
| Crystal Optics | |
| Refractive Indices | n=1.544 |
| Birefringence | |
| Optical Orientation | isotropic |
| Pleochroism | |
| Dispersion | |
| Used Literature | |
| {{{Literature}}} | |
Abstract[edit]
Occurrence[edit]
Sodium chloride is obtained through mining or derived from the sea or salt lakes and is commonly used for cooking or as deicing salt for roads.
The salt content of sea water is around 2.7 M.%.
Information on the origins and formation of halite on monuments[edit]
Sodium chloride can enter buildings or monuments when these are in contact with materials containing this salt or even other salts containing either sodium or chloride, that might react to produce NaCl efflorescence on them. Contamination with sodium and chloride ions can also occur through contact with salt laden ground or surface water. A range of cleaning materials (e.g., acidic and alkaline cleaners) and especially previously used restoration materials (e.g., water glass) or even Portland cement, can introduce sodium and chloride ions into monuments. Further common and important sources are deicing salts and maritime environments where the air and fogs may contain a significant amount of sodium chloride in suspension or dissolved in droplets.
Solubility behavior[edit]
The commonly occurring halite has a solubility of 358 g/l (20°C) and can be considered a very soluble and, therefore, easily mobilized salt. Its solubility changes comparatively little within a temperature range of 10 -30°C.
| Temperature | 10°C | 20°C | 40°C |
| Solubility [g/l] | 356,5 | 358,8 | 364,2 |
Hygroscopicity[edit]
Halite has a deliquescence humidity of about 75% RH, therefore it tends to pick up moisture easily in most temperate climates.
Moisture sorption:
Theoretically 1g NaCl can take up 4.3g of moisture, i.e., water vapor. The moisture sorption during varying relative humidity levels is:
| Relative humidity during storge/salt phase | NaCl |
| 87% RH | 153 |
| 81% RH | 22 |
| 79% RH | 7 |
Crystallization pressure[edit]
The crystallization of halite from an aqueous solution results in a crystallization pressure of 55,4-65,4 N/mm2 [Winkler:1975]Title: Stone: Properties, Durability in Man´s Environment
Author: Winkler, Erhard M.
(for comparison, the crystallization pressure of different salts can range from 7,2-65,4 N/mm2). These values need to be considered in conjunction with temperature and concentration and can, therefore, only act as indicators of damage potential in relation to salt crystallization pressure. In comparison to other salts, the crystallization pressure of halite is extremely high.
Hydration behavior[edit]
Under normal environmental conditions only halite will crystallize out of a saturated solution. The hydrated form, dihydrate hydrohalite[4] will only precipitate out at temperatures below 0.15°C.
Microscopy[edit]
Laboratory analysis[edit]
Sodium chloride crystals can be reliably identified on the basis of their morphological features. Individual particles usually form cubic or octahedral shapes and, therefore, clearly display right angles in their crystal construction.
Refractive index: nD = 1.544
Crystal category: cubic
Examination by polarized microscopy:
There are few salts belonging to the cubic crystal system which can be found in masonry, i.e., sodium chloride (halite), potassium chloride (sylvite) and calcium fluoride (flourite). Only two first salts are highly soluble and therefore they are the ones that can cause damage to the masonry. Because of its isotropic internal structure these salts do not display birefringence.
The classification of the refractive index occurs by immersion method in a standard oil with a refractive index of nD =1.518. Halite crystals display the same optical density in every direction so that the speed and orientation of linear polarized light waves are not distorted, therefore, when viewed between crossed polars, the crystals are not visible, i.e., they are "estinguished".
Differentiation of halite from similar salts:
The three above mentioned isotropic salts can be easily differentiated.
| Salt phase | Identification features |
| Sylvine KCl | Refractive index below1,518. |
| Fluorite CaF2 | Refractive index below 1,518, barely water soluble. |
Images of salts and salt damage[edit]
In situ[edit]
Halite crust on a brick surface
Halite whisker
Under the polarizing microscope[edit]
- Precipitate from watery sample on microscope slide
Sodium chloride, precipitate from an aqueous solution on microscope slide
Sodium chloride, precipitate from an aqueous solution on microscope slide
Sodium chloride, precipitate from an aqueous solution on microscope slide
Sodium chloride, precipitate from an aqueous solution on microscope slide
Sodium chloride, precipitate from an aqueous solution on microscope slide
Sodium chloride and calcium sulphate in real sample, precipitate from an aqueous solution on microscopic slide
Sodium chloride and calcium sulphate in real sample, precipitate from an aqueous solution on microscopic slide
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Weblinks[edit]
- ↑ http://webmineral.com/data/Halite.shtml accessed 28.07.2010
- ↑ http://www.mindat.org/min-1804.html accessed 28.07.2010
- ↑ http://www.mineralienatlas.de/lexikon/index.php/MineralData?mineral=Halit accessed 28.07.2010
- ↑ 4.0 4.1 http://www.mineralienatlas.de/lexikon/index.php/MineralData?mineral=Hydrohalit accessed 28.07.2010
Literature[edit]
| [Dana:1951] | Dana E.S. (eds.) Dana J.D. (1951): Dana's System of Mineralogy, 7, Wiley & Sons | |
| [Robie.etal:1978] | Robie R.A., Hemingway B.S.; Fisher J.A. (1978): Thermodynamic properties of minerals and related substances at 298.15 K and 1 bar pressure and higher temperatures. In: U.S. Geol. Surv. Bull, 1452 () | |
| [Steiger] | The entry doesn't exist yet. | |
| [Steiger.etal:2008c] | Steiger, Michael; Kiekbusch, Jana; Nicolai, Andreas (2008): An improved model incorporating Pitzer’s equations for calculation of thermodynamic properties of pore solutions implemented into an efficient program code. In: Construction and Building Materials, 22 (8), 1841-1850, 10.1016/j.conbuildmat.2007.04.020 | |
| [Steiger.etal:2014] | Steiger, Michael; Charola A. Elena; Sterflinger, Katja (2014): Weathering and Deterioration. In: Siegesmund S.; Snethlage R. (eds.): Stone in Architecture, Springer Verlag Berlin Heidelberg, 223-316, 10.1007/978-3-642-45155-3_4. | |
| [Vogt.etal:1993] | Vogt, R.; Goretzki, Lothar (1993): Der Einfluss hygroskopischer Salze auf die Gleichgewichtsfeuchte und Trocknung anorganischer Baustoffe, unveröffentlichter Bericht. | |
| [Winkler:1975] | Winkler, Erhard M. (1975): Stone: Properties, Durability in Man´s Environment, Springer Verlag, Wien | |
More Literature
| [Biscontin.etal:1988] | Biscontin, G.; Driussi, G.; Masin, A.; Zendri, E. (1988): Study on stones artificially salted with MgSO4*7H2O and NaCl and treated with siliconic resin. In: Ciabach, J. (eds.): Proceedings of the 6th International Congress on Deterioration and Conservation of Stone,Nicholas Copernicus University 194-206. | |
| [Brown.etal:2000] | Brown, P. W.; Badger, S. (2000): The distributions of bound sulfates and chlorides in concrete subjected to mixed NaCl, MgSO4, Na2SO4 attack. In: Cem. Concr. Res., 30 (10), 1535-1542 | |
| [Brown.etal:2001] | Brown, P. W.; Badger, S. (2001): Reply to the discussion by William G. Hime and Stella L. Marusin of the paper "The distribution of bound sulfates and chlorides in concrete to mixed NaCl, MgSO4, Na2SO4 attack". In: Cem. Concr. Res., 31 (7), 1117-1118 | |
| [Dorn.etal:2007] | Dorn, Joachim; Steiger, Michael (2007): Measurement and Calculation of Solubilities in the Ternary System NaCH3COO + NaCl + H2O from 278 K to 323 K. In: Journal of Chemical and Engineering Data, 5 (52), 1784-1790, 10.1021/je7001495 | |
| [Friedel:1978] | Friedel, B. (1978): Gipslöslichkeiten in wässerigen Systemen mit NaCl, MgCl2, Na2SO4 und MgSO4. In: Zeitschrift für Pflanzenernährung und Bodenkunde, 141 (3), 337-346, 10.1002/jpln.19781410309 | |
| [Glasner.etal:1974] | Glasner, A.; Zidon, M. (1974): The crystallization of NaCl in the presence of (Fe(CN)6)4- ions. In: Journal of Crystal Growth, 21 (2), 294-304, 10.1016/0022-0248(74)90018-9 | |
| [Linnow.etal:2007c] | Linnow, Kirsten; Juling, Herbert; Steiger, Michael (2007): Investigation of NaCl deliquescence in porous substrates using RH-XRD. In: Environmental Geology, 52 (2), 317-327, 10.1007/s00254-006-0590-9 | |
| [Lubelli.etal:2006] | Lubelli, B.; van Hees, R.P.J.; Huinik, H.P.; Groot, C.J.W.P. (2006): Irreversible dilation of NaCl contaminated lime–cement mortar due to crystallization cycles. In: Cement and Concrete Research, 36 (4), 678-687, 10.1016/j.cemconres.2005.10.008 | |
| [Lubelli.etal:2006a] | Lubelli, B.; van Hees, R.P.J.; Huinink, H.P. (2006): Effect of NaCl on the hydric and hygric dilation behaviour of lime-cement mortar. In: HERON, 51 (1), 33-48 |  |
| [Marliacy.etal:2000] | Marliacy, P.; Solimando, R.; Bouroukba, M.; Schuffenecker, L. (2000): Thermodynamics of crystallization of sodium sulfate decahydrate in H2O-NaCl-Na2SO4: application to Na2SO4.cntdot.10H2O-based latent heat storage materials. In: Thermochim. Acta, 344 (1), 85-94 | |
| [Monnin:1990] | Monnin, C. (1990): The influence of pressure on the activity coefficients of the solutes and on the solubility of minerals in the system Na-Ca-Cl-SO4-H2O to 200°C and 1 kbar, and to high NaCl concentration. In: Geochimica et Cosmochimica Acta, 54 (12), 3265-3282, 10.1016/0016-7037(90)90284-R | |
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