Sodium silicate
- E550 redirects here. For the Italian locomotive, see FS Class E550
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| Names | |
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| IUPAC name
Sodium metasilicate
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| Other names
Waterglass
Liquid glass E550 | |
| Identifiers | |
| EC Number |
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PubChem CID
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| RTECS number |
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| Properties | |
| Na2SiO3 | |
| Molar mass | 122.06 g/mol (anhydrous) 212.14 g/mol (pentahydrate) |
| Appearance | colorless solid |
| Density | 2.4 g/cm3, solid |
| Melting point | 1088 °C (anhydrous) 72.2 °C (pentahydrate) |
| Soluble | |
Refractive index (nD)
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1.52 (anhydrous) 1.456 (pentahydrate) |
| Thermochemistry | |
Std molar
entropy (S⦵298) |
113.8 J K−1 mol−1 |
Std enthalpy of
formation (ΔfH⦵298) |
−1519 kJ/mol |
| Hazards | |
| NFPA 704 (fire diamond) | |
| Related compounds | |
Other anions
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Sodium carbonate Sodium germanate Sodium stannate Sodium plumbate |
Other cations
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Potassium silicate |
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Sodium silicate is the common name for a compound sodium metasilicate, Na2SiO3, also known as water glass or liquid glass. It is available in aqueous solution and in solid form and is used in cements, passive fire protection, refractories, textile and lumber processing, and automobiles. Sodium carbonate and silicon dioxide react when molten to form sodium silicate and carbon dioxide[1]:
- Na2CO3 + SiO2 → Na2SiO3 + CO2
Anhydrous sodium silicate contains a chain polymeric anion composed of corner shared {SiO4} tetrahedra, and not a discrete SiO32− ion[1]. In addition to the anhydrous form there are a number of hydrates with the formulae Na2SiO3.nH2O (where n= 5, 6, 8, 9) which contain the discrete approximately tetrahedral anion SiO2(OH)22− with water of hydration e.g. the commercially available sodium silicate pentahydrate, Na2SiO3.5H2O is formulated Na2SiO2(OH)2.4H2O and the nonahydrate, Na2SiO3.9H2O is formulated Na2SiO2(OH)2.8H2O .[2]
Properties
Sodium silicate is a white powder that is readily soluble in water, producing an alkaline solution. It is one of a number of related compounds which include sodium orthosilicate, Na4SiO4; sodium pyrosilicate, Na6Si2O7, and others. All are glassy, colourless and dissolve in water.
Sodium silicate is stable in neutral and alkaline solutions. In acidic solutions, the silicate ion reacts with hydrogen ions to form silicic acid, which when heated and roasted forms silica gel, a hard, glassy and cheesy/smelly substance.
CAS registry number and EINECS number
Each and every substance has its own unique CAS registry number and EINECS number. ESIS (European chemical Substances Information System)is an IT System which provides you with information on chemicals, related to:
EINECS (European Inventory of Existing Commercial chemical Substances) O.J. C 146A, 15.6.1990, ELINCS (European List of Notified Chemical Substances) in support of Directive 92/32/EEC, the 7th amendment to Directive 67/548/EEC, NLP (No-Longer Polymers),
As per this system, CAS No. and EINECS No. of Sodium silicate and other related substances are as per given in following table.
| Substance Name | CAS# | EC#(EINECS No.) |
|---|---|---|
| sodium silicate | 15859-24-2 | 239-981-7 |
| disodium metasilicate | 6834-92-0 | 229-912-9 |
| Silicic acid, sodium salt | 1344-09-8 | 215-687-4 |
Uses
Metal repair
Sodium silicate is used, along with magnesium silicate, in muffler repair and fitting paste. When dissolved in water, both sodium silicate, and magnesium silicate form a thick paste that is easy to apply. When the exhaust system of an internal combustion engine heats up to its operating temperature, the heat drives out all of the excess water from the paste. The silicate compounds that are left over have glass-like properties, making a somewhat permanent, brittle repair.
Automotive repair
Sodium silicate can be used to seal leaks at the head gasket. A common use is when an alloy cylinder head engine is left sitting for extended periods or the coolant is not changed at proper intervals, electrolysis can "eat out" sections of the head causing the gasket to fail.
Rather than remove the cylinder head, "liquid glass" is poured into the radiator and allowed to circulate. The waterglass is injected via the radiator water into the hotspot at the engine. This technique works because at 210–220 °F the sodium silicate loses water molecules to form a very powerful sealant that will not re-melt below 1500 °F.
A sodium silicate repair of a leaking head gasket can hold for up to two years and even longer in some cases. The effect will be almost instant, and steam from the radiator water will stop coming out the exhaust within minutes of application. This repair only works with water-to-cylinder or water-to-air applications and where the sodium silicate reaches the "conversion" temperature of 210–220 °F.
Car engine disablement
Sodium silicate solution is used to inexpensively, quickly, and permanently disable automobile engines. Running an engine with two quarts of a sodium silicate solution instead of motor oil causes the solution to precipitate, catastrophically damaging the engine's bearings and pistons within a few minutes.[4] In the United States this procedure is required by the Car Allowance Rebate System (CARS) program.[4][5]
Aquaculture
Sodium silicate gel is also used as a substrate algal growth in aquaculture hatcheries.
Cement uses
Sodium silicate has been widely used as a general purpose cement, but especially for applications involving cementing objects exposed to heat or fire. For example, sodium silicate has been provided in home first-aid kits and used in medical practice as a glue for holding human skin together at surface cuts. It has also been used as a general purpose paper cement.
One common example of its use as a paper cement was for producing paper cartridges for black powder revolvers produced by Colt's Manufacturing Company during the period from 1851 until 1873, especially during the American Civil War. Sodium silicate was used to seal combustible nitrated paper together to form a conical paper cartridge to hold the black powder, as well as to cement the lead ball or conical bullet into the open end of the paper cartridge. Such sodium silicate cemented paper cartridges were inserted into the cylinders of revolvers, thereby speeding the reloading of cap and ball black powder revolvers. This use largely ended with the introduction of Colt revolvers employing brass-cased cartridges starting in 1873.
When used as a paper cement, the tendency is for the sodium silicate joint eventually to crack within a few years, at which point it no longer holds the paper surfaces cemented together.
Food preservation
Sodium silicate was also used as an egg preservation agent in the early 20th Century with large success. When fresh eggs are immersed in it, bacteria which cause the eggs to spoil are kept out and water is kept in. Eggs can be kept fresh using this method for up to nine months. When boiling eggs preserved this way, it is well advised to pin-prick the egg to allow steam to escape because the shell is no longer porous.
An article in The Mother Earth News offers test results for this and other methods of preservation. LINK
Timber treatment
The use of sodium silicate as a timber treatment for pressure-treated wood began some time in the 19th century. It is suggested that that more costly "silicate of potash" (potassium silicate) may also be used, in "Handy Farm Devices and How to Make Them" by Rolfe Cobleigh, published in 1910. Since 1998 scientists have researched methods for rendering sodium silicate insoluble once the lumber has been treated with it. With or without the additional process, treating wood with sodium silicate preserves wood from insects and possesses some flame-retardant properties.
Concrete and general masonry treatment
Concrete treated with a sodium silicate solution helps to significantly reduce porosity in most masonry products such as concrete, stucco, plasters. A chemical reaction occurs with the excess Ca(OH)2 in the concrete that permanently binds the silicates with the surface making them far more wearable and water repellent. It is generally advised to apply only after initial cure has taken place (7 days or so depending on conditions). These coatings are known as silicate mineral paint.
Passive fire protection ("PFP")
Sodium silicates are inherently intumescent. They come in prill (solid beads) form, as well as the liquid, water glass. The solid sheet form (Palusol) must be waterproofed to ensure longterm passive fire protection.
Standard, solid, bead form sodium silicates have been used as aggregate within silicone rubber to manufacture plastic pipe firestop devices. The silicone rubber was insufficient waterproofing to preserve the intumescing function and the products had to be recalled, which is problematic for firestops that are concealed behind drywall in buildings.
Pastes for caulking purposes are similarly unstable. This too has resulted in recalls and even litigation. Only 3M's "Expantrol" version, which has an external heat treatment that helps to seal the outer surface, as part of its process standard, has achieved sufficient longevity to qualify for DIBt [1] approvals in the US for use in firestopping.
Not unlike other intumescents, sodium silicate, both in bead form and in liquid form are inherently endothermic, due to liquid water in the water glass and hydrates in the prill form. The absence in the US of mandatory aging tests, whereby PFP systems are made to undergo system performance tests after the aging and humidity exposures, are at the root of the continued availability, in North America, of PFP products that can become inoperable within weeks of installation. Indiscriminate use of sodium silicates without proper waterproofing measures are contributors to the problems and risk. When sodium silicates are adequately protected, they function extremely well and reliably for long. Evidence of this can be seen in the many DIBt approvals for plastic pipe firestop devices using Palusol, which use waterproofed sodium silicate sheets.
Refractory use
Water glass is a useful binder of solids, such as vermiculite and perlite. When blended with the aforementioned lightweight aggregates, water glass can be used to make hard, high-temperature insulation boards used for refractories, passive fire protection and high temperature insulations, such as moulded pipe insulation applications. When mixed with finely divided mineral powders, such as vermiculite dust (which is common scrap from the exfoliation process), one can produce high temperature adhesives. The intumescence disappears in the presence of finely divided mineral dust, whereby the waterglass becomes a mere matrix. Waterglass is inexpensive and abundantly available, which makes its use popular in many refractory applications.
Water treatment
Water glass is used as a water treatment in waste water treatment plants. Waterglass will bind to heavier molecules and drag them out of the water. [citation needed]
Magic crystals
Water glass was used in the magic crystal garden toys from the 1980s. When waterglass was combined with a selection of different metals in solution, the waterglass would cause the metals to precipitate. Each metal would precipitate separately causing a different color stalagmite.
An early mention of crystals of metallic salts forming a "chemical garden" in sodium silicate is found in the 1946 Modern Mechanix magazine [2]. This results in very colorful gardens—much more than shown in the illustrations. Use caution with the metal salts if you do this, some are dangerous to people and animals if swallowed.
In Europe the ingredients for such chemical gardens were available already around the early 1930s. Interestingly enough, one could buy these at better flower shops in Budapest, Hungary.[citation needed] Used in making condoms.
See also
References
- ^ a b Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8.
- ^ Wells A.F. (1984) Structural Inorganic Chemistry 5th edition Oxford Science Publications ISBN 0-19-855370-6
- ^ http://ecb.jrc.ec.europa.eu/esis/
- ^ a b Helliker, Kevin. "The Killer App for Clunkers Breathes Fresh Life Into 'Liquid Glass'" The Wall Street Journal, 4 August 2009.
- ^ http://www.cars.gov/files/disposal-salvage/engine-disablement-procedures.pdf