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Mountain soap has the same properties as one of its main varieties: [[bentonite]] or [[montmorillonite]]. This is a typical clay mineral belonging to the subclass of layered silicates, due to its structure it has the ability to swell strongly. In addition, mountain soap has pronounced sorption properties. The modern use of bentonites in industrial production, construction and even as a food additive is based on their high thermal stability, binding ability, as well as [[Catalysis|catalytic]] and [[adsorption]] activity. |
Mountain soap has the same properties as one of its main varieties: [[bentonite]] or [[montmorillonite]]. This is a typical clay mineral belonging to the subclass of layered silicates, due to its structure it has the ability to swell strongly. In addition, mountain soap has pronounced sorption properties. The modern use of bentonites in industrial production, construction and even as a food additive is based on their high thermal stability, binding ability, as well as [[Catalysis|catalytic]] and [[adsorption]] activity. |
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Old authors of the 18th-19th centuries, describing the properties of mountain soap, unanimously note that it is opaque, not sticky, convenient for writing, and also soft when wetted, lathers well and sticks strongly to the tongue. It feels greasy and light. In composition (according to Buchholz's analysis) it contains 44% [[Silicon dioxide|silica]], 26.5% [[Aluminium oxide|alumina]], about 20.5% [[water]], 8% [[iron oxide]]s and 0.5-1% [[calcium]] compounds ([[lime]]).<ref name="fish">''[[Gotthelf Fischer von Waldheim|Fischer von Waldheim G.I.]]'' Oryctognosy or a brief description of all fossil substances with an explanation of terms: Part one. Essay by Gottgelf Fischer, Imperial Medical-Surgical Academy Vice-President. — Moscow: Printing house of the Imperial Medical-Surgical Academy, 1818. — 456 p.</ref>{{rp|377-378}} |
Old authors of the 18th-19th centuries, describing the properties of mountain soap, unanimously note that it is opaque, not sticky, convenient for writing, and also soft when wetted, lathers well and sticks strongly to the tongue. It feels greasy and light. In composition (according to Buchholz's analysis) it contains 44% [[Silicon dioxide|silica]], 26.5% [[Aluminium oxide|alumina]], about 20.5% [[water]], 8% [[iron oxide]]s and 0.5-1% [[calcium]] compounds ([[lime]]).<ref name="fish">''[[Gotthelf Fischer von Waldheim|Fischer von Waldheim G.I.]]'' Oryctognosy or a brief description of all fossil substances with an explanation of terms: Part one. Essay by Gottgelf Fischer, Imperial Medical-Surgical Academy Vice-President. — Moscow: Printing house of the Imperial Medical-Surgical Academy, 1818. — 456 p.</ref>{{rp|377-378}} Naturally, the results of chemical analysis relate exclusively to the specific variety on which laboratory operations were carried out. In all other cases, both the percentage composition of the substances that make up the clay and the set of impurities may differ significantly from the proposed ratio. Nevertheless, this analysis is quite indicative in general for that mineral group that can be described as “mountain soaps”. |
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Being in damp soil or being moistened, mountain soap becomes completely soft and similar to butter, but when it dries in dry weather in the air or when heated, it hardens. Chemical stability and even some inertness of mountain soap are also noted; even in strong acids, for example, sulfuric, hydrochloric or nitric, no visible change or any other signs of a chemical reaction occur with it.<ref name="Mining">Mining magazine or collection of information about mining and salt business. — St. Petersburg: Printing house of the Mountain Cadet Corps, 1826.</ref>{{rp|157}} |
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== Gallery == |
== Gallery == |
Revision as of 12:32, 5 April 2024
Mountain soap | |
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General | |
Category | Mineral |
Mountain soap (Latin: Argilla saponiformis, German: Bergseife, French: Savon de montagne),[1]: 203 — a partially outdated trivial name for a large group of clay minerals similar in properties from the group of hydrous layered aluminum silicates with variable composition. Minerals from the mountain soap group contain primarily silicates (44-46%), alumina (17-26%), iron oxides (6-10%) and water (13-25%). The mountain soap group included at different times up to two dozen mineral species and varieties. In different cases, this name could mean different minerals, most often halloysite (from the proper name), saponite (soapstone),[2]: 187 bentonite or montmorillonite (from the French: Montmorillon, toponym). The last mineral is a large group, each of which could be called mountain soap. All these minerals received their common colloquial name, which gradually penetrated into mineralogy, for their ability to lather and serve as a detergent for various purposes.
Mountain soap has some common properties that are characteristic of all minerals included in the group. All of them have very low hardness (from 1 to 2 on the Mohs scale) and are a typical weathering product of aluminosilicates. In the form of its main component (bentonite, which is formed during the weathering of volcanic rocks — tuffs and ash), mountain soap is one of the main minerals in many types of soils, and it is also found in many sedimentary rocks. Thanks to its layered “batch” structure, mountain soap has the ability to absorb water, swell strongly and has pronounced sorption properties.
Name
The name “mountain soap” is not so much a metaphor, which is quite often found in mineralogy, as a simple statement of the soapy properties of the mineral, as well as the systematic use that it has had for thousands of years. On the one hand, this type of clay received its trivial name from its property of softening in water and forming with it a viscous and greasy substance to the touch, similar to thickly diluted soap.[3]: 95 On the other hand, for a very long time, the population that had access to deposits of such clays systematically used it as a detergent for various purposes: from waulking cloth, canvas and wool to washing hands, face and hair in the bathhouse.[4] From the combination of two factors inherent in all these varieties, other synonymous names also follow under which washing clays are found. In the literature of the 18th and 19th centuries, mountain soap can be found under the names: soapy earth,[5] soapy clay, soapstone or bolus.[6]
The conventional scientific use of the collective term “mountain soap” generally ended by the last quarter of the 19th century, giving way to individual names of the minerals included in this conventional group. Currently, the term is considered completely outdated and does not appear as such even in the latest mineralogical dictionaries.[7]: 239, 531
Properties
Mountain soap has the same properties as one of its main varieties: bentonite or montmorillonite. This is a typical clay mineral belonging to the subclass of layered silicates, due to its structure it has the ability to swell strongly. In addition, mountain soap has pronounced sorption properties. The modern use of bentonites in industrial production, construction and even as a food additive is based on their high thermal stability, binding ability, as well as catalytic and adsorption activity.
Old authors of the 18th-19th centuries, describing the properties of mountain soap, unanimously note that it is opaque, not sticky, convenient for writing, and also soft when wetted, lathers well and sticks strongly to the tongue. It feels greasy and light. In composition (according to Buchholz's analysis) it contains 44% silica, 26.5% alumina, about 20.5% water, 8% iron oxides and 0.5-1% calcium compounds (lime).[8]: 377–378 Naturally, the results of chemical analysis relate exclusively to the specific variety on which laboratory operations were carried out. In all other cases, both the percentage composition of the substances that make up the clay and the set of impurities may differ significantly from the proposed ratio. Nevertheless, this analysis is quite indicative in general for that mineral group that can be described as “mountain soaps”.
Being in damp soil or being moistened, mountain soap becomes completely soft and similar to butter, but when it dries in dry weather in the air or when heated, it hardens. Chemical stability and even some inertness of mountain soap are also noted; even in strong acids, for example, sulfuric, hydrochloric or nitric, no visible change or any other signs of a chemical reaction occur with it.[9]: 157
Gallery
References
- ^ Nikolay Shcheglov, Mineralogy according to Mr. Haüy′s system: part two. — St. Petersburg: In Marine Printing House, 1824.
- ^ A. N. Krishtofovich, Geological Dictionary. Volume 1. — Moscow: State Publishing House of Geological Literature, 1955.
- ^ Spassky G. I. Mountain dictionary. Part one. — S. Petersburg. In the printing house of Nikolai Stepanov, 1843.
- ^ Ogorodnikov P. I. ″Essays on Persia″. Shahrud kaleidoscope. Persian coast of the Caspian Sea. Pass over Kuzluk. — S. Petersburg: ed. magazine ″World Traveler″, 1878. — 396 p.
- ^ Guide to Mathematical and Physical Geography, with the use of the earth's globe and land maps, again translated with notes from French. Theodore Ulr. Theod. Epimus (translation by A. M. Razumov). Second edition. — In St. Petersburg at the Imperial Academy of Sciences in 1764.
- ^ Steller Georg Wilhelm. Description of the land of Kamchatka. — Petropavlovsk-Kamchatsky: Kamchatka Printing Yard. Book Publishing house, 1999.
- ^ Krivovichev V. G. Mineralogical glossary. Scientific editor A. G. Bulakh. — St.Petersburg: St.Petersburg Univ. Publ. House. 2009. — 556 p. — ISBN 978-5-288-04863-0
- ^ Fischer von Waldheim G.I. Oryctognosy or a brief description of all fossil substances with an explanation of terms: Part one. Essay by Gottgelf Fischer, Imperial Medical-Surgical Academy Vice-President. — Moscow: Printing house of the Imperial Medical-Surgical Academy, 1818. — 456 p.
- ^ Mining magazine or collection of information about mining and salt business. — St. Petersburg: Printing house of the Mountain Cadet Corps, 1826.