Silicon dioxide

(Redirected from SiO2)

Silicon dioxide, also known as silica, is an oxide of silicon with the chemical formula SiO2, commonly found in nature as quartz.[5][6] In many parts of the world, silica is the major constituent of sand. Silica is one of the most complex and abundant families of materials, existing as a compound of several minerals and as a synthetic product. Examples include fused quartz, fumed silica, opal, and aerogels. It is used in structural materials, microelectronics, and as components in the food and pharmaceutical industries. All forms are white or colorless, although impure samples can be colored.

Silicon dioxide

A sample of silicon dioxide
Names
IUPAC name
Silicon dioxide
Other names
  • Quartz
  • Silica
  • Silicic oxide
  • Silicon(IV) oxide
  • Crystalline silica
  • Pure Silica
  • Silicea
  • Silica sand
Identifiers
ChEBI
ChemSpider
ECHA InfoCard 100.028.678 Edit this at Wikidata
EC Number
  • 231-545-4
E number E551 (acidity regulators, ...)
200274
KEGG
MeSH Silicon+dioxide
RTECS number
  • VV7565000
UNII
  • InChI=1S/O2Si/c1-3-2 checkY
    Key: VYPSYNLAJGMNEJ-UHFFFAOYSA-N checkY
Properties
SiO2
Molar mass 60.08 g/mol
Appearance Transparent or white
Density 2.648 (α-quartz), 2.196 (amorphous) g·cm−3[1]
Melting point 1,713 °C (3,115 °F; 1,986 K) (amorphous)[1]: 4.88 
Boiling point 2,950 °C (5,340 °F; 3,220 K)[1]
−29.6·10−6 cm3/mol
Thermal conductivity 12 (|| c-axis), 6.8 (⊥ c-axis), 1.4 (am.) W/(m⋅K)[1]: 12.213 
1.544 (o), 1.553 (e)[1]: 4.143 
Hazards
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 0: Exposure under fire conditions would offer no hazard beyond that of ordinary combustible material. E.g. sodium chlorideFlammability 0: Will not burn. E.g. waterInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
0
0
0
NIOSH (US health exposure limits):
PEL (Permissible)
TWA 20 mppcf (80 mg/m3/%SiO2) (amorphous)[2]
REL (Recommended)
TWA 6 mg/m3 (amorphous)[2]
Ca TWA 0.05 mg/m3[3]
IDLH (Immediate danger)
3000 mg/m3 (amorphous)[2]
Ca [25 mg/m3 (cristobalite, tridymite); 50 mg/m3 (quartz)][3]
Related compounds
Related diones
Carbon dioxide
Germanium dioxide
Tin dioxide
Lead dioxide
Related compounds
Silicon monoxide
Silicon disulfide
Thermochemistry
42 J·mol−1·K−1[4]
−911 kJ·mol−1[4]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
☒N verify (what is checkY☒N ?)

Silicon dioxide is a common fundamental constituent of glass.

Structure

edit
 
Structural motif found in α-quartz, but also found in almost all forms of silicon dioxide
 
Typical subunit for low pressure silicon dioxide
 
Relationship between refractive index and density for some SiO2 forms[7]

In the majority of silicon dioxides, the silicon atom shows tetrahedral coordination, with four oxygen atoms surrounding a central Si atom (see 3-D Unit Cell). Thus, SiO2 forms 3-dimensional network solids in which each silicon atom is covalently bonded in a tetrahedral manner to 4 oxygen atoms.[8][9] In contrast, CO2 is a linear molecule. The starkly different structures of the dioxides of carbon and silicon are a manifestation of the double bond rule.[10]

Based on the crystal structural differences, silicon dioxide can be divided into two categories: crystalline and non-crystalline (amorphous). In crystalline form, this substance can be found naturally occurring as quartz, tridymite (high-temperature form), cristobalite (high-temperature form), stishovite (high-pressure form), and coesite (high-pressure form). On the other hand, amorphous silica can be found in nature as opal and diatomaceous earth. Quartz glass is a form of intermediate state between these structures.[11]

All of these distinct crystalline forms always have the same local structure around Si and O. In α-quartz the Si–O bond length is 161 pm, whereas in α-tridymite it is in the range 154–171 pm. The Si–O–Si angle also varies between a low value of 140° in α-tridymite, up to 180° in β-tridymite. In α-quartz, the Si–O–Si angle is 144°.[12]

Polymorphism

edit

Alpha quartz is the most stable form of solid SiO2 at room temperature. The high-temperature minerals, cristobalite and tridymite, have both lower densities and indices of refraction than quartz. The transformation from α-quartz to beta-quartz takes place abruptly at 573 °C. Since the transformation is accompanied by a significant change in volume, it can easily induce fracturing of ceramics or rocks passing through this temperature limit.[13] The high-pressure minerals, seifertite, stishovite, and coesite, though, have higher densities and indices of refraction than quartz.[14] Stishovite has a rutile-like structure where silicon is 6-coordinate. The density of stishovite is 4.287 g/cm3, which compares to α-quartz, the densest of the low-pressure forms, which has a density of 2.648 g/cm3.[15] The difference in density can be ascribed to the increase in coordination as the six shortest Si–O bond lengths in stishovite (four Si–O bond lengths of 176 pm and two others of 181 pm) are greater than the Si–O bond length (161 pm) in α-quartz.[16] The change in the coordination increases the ionicity of the Si–O bond.[17]

Faujasite silica, another polymorph, is obtained by the dealumination of a low-sodium, ultra-stable Y zeolite with combined acid and thermal treatment. The resulting product contains over 99% silica, and has high crystallinity and specific surface area (over 800 m2/g). Faujasite-silica has very high thermal and acid stability. For example, it maintains a high degree of long-range molecular order or crystallinity even after boiling in concentrated hydrochloric acid.[18]

Molten SiO2

edit

Molten silica exhibits several peculiar physical characteristics that are similar to those observed in liquid water: negative temperature expansion, density maximum at temperatures ~5000 °C, and a heat capacity minimum.[19] Its density decreases from 2.08 g/cm3 at 1950 °C to 2.03 g/cm3 at 2200 °C.[20]

Molecular SiO2

edit

The molecular SiO2 has a linear structure like CO2. It has been produced by combining silicon monoxide (SiO) with oxygen in an argon matrix. The dimeric silicon dioxide, (SiO2)2 has been obtained by reacting O2 with matrix isolated dimeric silicon monoxide, (Si2O2). In dimeric silicon dioxide there are two oxygen atoms bridging between the silicon atoms with an Si–O–Si angle of 94° and bond length of 164.6 pm and the terminal Si–O bond length is 150.2 pm. The Si–O bond length is 148.3 pm, which compares with the length of 161 pm in α-quartz. The bond energy is estimated at 621.7 kJ/mol.[21]

Natural occurrence

edit

Geology

edit
 

SiO2 is most commonly encountered in nature as quartz, which comprises more than 10% by mass of the Earth's crust.[22] Quartz is the only polymorph of silica stable at the Earth's surface. Metastable occurrences of the high-pressure forms coesite and stishovite have been found around impact structures and associated with eclogites formed during ultra-high-pressure metamorphism. The high-temperature forms of tridymite and cristobalite are known from silica-rich volcanic rocks. In many parts of the world, silica is the major constituent of sand.[23]

Biology

edit

Even though it is poorly soluble, silica occurs in many plants such as rice. Plant materials with high silica phytolith content appear to be of importance to grazing animals, from chewing insects to ungulates. Silica accelerates tooth wear, and high levels of silica in plants frequently eaten by herbivores may have developed as a defense mechanism against predation.[24][25]

Silica is also the primary component of rice husk ash, which is used, for example, in filtration and as supplementary cementitious material (SCM) in cement and concrete manufacturing.[26]

Silicification in and by cells has been common in the biological world and it occurs in bacteria, protists, plants, and animals (invertebrates and vertebrates).[27]

Prominent examples include:

Uses

edit

Structural use

edit

About 95% of the commercial use of silicon dioxide (sand) is in the construction industry, e.g. in the production of concrete (Portland cement concrete).[22]

Certain deposits of silica sand, with desirable particle size and shape and desirable clay and other mineral content, were important for sand casting of metallic products.[33] The high melting point of silica enables it to be used in such applications such as iron casting; modern sand casting sometimes uses other minerals for other reasons.

Crystalline silica is used in hydraulic fracturing of formations which contain tight oil and shale gas.[34]

Precursor to glass and silicon

edit

Silica is the primary ingredient in the production of most glass. As other minerals are melted with silica, the principle of freezing point depression lowers the melting point of the mixture and increases fluidity. The glass transition temperature of pure SiO2 is about 1475 K.[35] When molten silicon dioxide SiO2 is rapidly cooled, it does not crystallize, but solidifies as a glass.[36] Because of this, most ceramic glazes have silica as the main ingredient.[37]

The structural geometry of silicon and oxygen in glass is similar to that in quartz and most other crystalline forms of silicon and oxygen, with silicon surrounded by regular tetrahedra of oxygen centres. The difference between the glass and crystalline forms arises from the connectivity of the tetrahedral units: Although there is no long-range periodicity in the glassy network, ordering remains at length scales well beyond the SiO bond length. One example of this ordering is the preference to form rings of 6-tetrahedra.[38]

The majority of optical fibers for telecommunications are also made from silica. It is a primary raw material for many ceramics such as earthenware, stoneware, and porcelain.

Silicon dioxide is used to produce elemental silicon. The process involves carbothermic reduction in an electric arc furnace:[39]

 

Fumed silica

edit

Fumed silica, also known as pyrogenic silica, is prepared by burning SiCl4 in an oxygen-rich hydrogen flame to produce a "smoke" of SiO2.[15]

 

It can also be produced by vaporizing quartz sand in a 3000 °C electric arc. Both processes result in microscopic droplets of amorphous silica fused into branched, chainlike, three-dimensional secondary particles which then agglomerate into tertiary particles, a white powder with extremely low bulk density (0.03-0.15 g/cm3) and thus high surface area.[40] The particles act as a thixotropic thickening agent, or as an anti-caking agent, and can be treated to make them hydrophilic or hydrophobic for either water or organic liquid applications.

 
Manufactured fumed silica with maximum surface area of 380 m2/g

Silica fume is an ultrafine powder collected as a by-product of the silicon and ferrosilicon alloy production. It consists of amorphous (non-crystalline) spherical particles with an average particle diameter of 150 nm, without the branching of the pyrogenic product. The main use is as pozzolanic material for high performance concrete. Fumed silica nanoparticles can be successfully used as an anti-aging agent in asphalt binders.[41]

Food, cosmetic, and pharmaceutical applications

edit

Silica, either colloidal, precipitated, or pyrogenic fumed, is a common additive in food production. It is used primarily as a flow or anti-caking agent in powdered foods such as spices and non-dairy coffee creamer, or powders to be formed into pharmaceutical tablets.[40] It can adsorb water in hygroscopic applications. Colloidal silica is used as a fining agent for wine, beer, and juice, with the E number reference E551.[22]

In cosmetics, silica is useful for its light-diffusing properties[42] and natural absorbency.[43]

Diatomaceous earth, a mined product, has been used in food and cosmetics for centuries. It consists of the silica shells of microscopic diatoms; in a less processed form it was sold as "tooth powder".[44][45] Manufactured or mined hydrated silica is used as the hard abrasive in toothpaste.

Semiconductors

edit

Silicon dioxide is widely used in the semiconductor technology:

  • for the primary passivation (directly on the semiconductor surface),
  • as an original gate dielectric in MOS technology. Today when scaling (dimension of the gate length of the MOS transistor) has progressed below 10 nm, silicon dioxide has been replaced by other dielectric materials like hafnium oxide or similar with higher dielectric constant compared to silicon dioxide,
  • as a dielectric layer between metal (wiring) layers (sometimes up to 8–10) connecting elements and
  • as a second passivation layer (for protecting semiconductor elements and the metallization layers) typically today layered with some other dielectrics like silicon nitride.

Because silicon dioxide is a native oxide of silicon it is more widely used compared to other semiconductors like gallium arsenide or indium phosphide.

Silicon dioxide could be grown on a silicon semiconductor surface.[46] Silicon oxide layers could protect silicon surfaces during diffusion processes, and could be used for diffusion masking.[47][48]

Surface passivation is the process by which a semiconductor surface is rendered inert, and does not change semiconductor properties as a result of interaction with air or other materials in contact with the surface or edge of the crystal.[49][50] The formation of a thermally grown silicon dioxide layer greatly reduces the concentration of electronic states at the silicon surface.[50] SiO2 films preserve the electrical characteristics of p–n junctions and prevent these electrical characteristics from deteriorating by the gaseous ambient environment.[48] Silicon oxide layers could be used to electrically stabilize silicon surfaces.[47] The surface passivation process is an important method of semiconductor device fabrication that involves coating a silicon wafer with an insulating layer of silicon oxide so that electricity could reliably penetrate to the conducting silicon below. Growing a layer of silicon dioxide on top of a silicon wafer enables it to overcome the surface states that otherwise prevent electricity from reaching the semiconducting layer.[49][51]

The process of silicon surface passivation by thermal oxidation (silicon dioxide) is critical to the semiconductor industry. It is commonly used to manufacture metal–oxide–semiconductor field-effect transistors (MOSFETs) and silicon integrated circuit chips (with the planar process).[49][51]

Other

edit

Hydrophobic silica is used as a defoamer component.

In its capacity as a refractory, it is useful in fiber form as a high-temperature thermal protection fabric.[52]

Silica is used in the extraction of DNA and RNA due to its ability to bind to the nucleic acids under the presence of chaotropes.[53]

Silica aerogel was used in the Stardust spacecraft to collect extraterrestrial particles.[54]

Pure silica (silicon dioxide), when cooled as fused quartz into a glass with no true melting point, can be used as a glass fibre for fibreglass.

Production

edit

Silicon dioxide is mostly obtained by mining, including sand mining and purification of quartz. Quartz is suitable for many purposes, while chemical processing is required to make a purer or otherwise more suitable (e.g. more reactive or fine-grained) product.[55][56]

Precipitated silica

edit

Precipitated silica or amorphous silica is produced by the acidification of solutions of sodium silicate. The gelatinous precipitate or silica gel, is first washed and then dehydrated to produce colorless microporous silica.[15] The idealized equation involving a trisilicate and sulfuric acid is:

 

Approximately one billion kilograms/year (1999) of silica were produced in this manner, mainly for use for polymer composites – tires and shoe soles.[22]

On microchips

edit

Thin films of silica grow spontaneously on silicon wafers via thermal oxidation, producing a very shallow layer of about 1 nm or 10 Å of so-called native oxide.[57] Higher temperatures and alternative environments are used to grow well-controlled layers of silicon dioxide on silicon, for example at temperatures between 600 and 1200 °C, using so-called dry oxidation with O2

 

or wet oxidation with H2O.[58][59]

 

The native oxide layer is beneficial in microelectronics, where it acts as electric insulator with high chemical stability. It can protect the silicon, store charge, block current, and even act as a controlled pathway to limit current flow.[60]

Laboratory or special methods

edit

From organosilicon compounds

edit

Many routes to silicon dioxide start with an organosilicon compound, e.g., HMDSO,[61] TEOS. Synthesis of silica is illustrated below using tetraethyl orthosilicate (TEOS).[62] Simply heating TEOS at 680–730 °C results in the oxide:

 

Similarly TEOS combusts around 400 °C:

 

TEOS undergoes hydrolysis via the so-called sol-gel process. The course of the reaction and nature of the product are affected by catalysts, but the idealized equation is:[63]

 

Other methods

edit

Being highly stable, silicon dioxide arises from many methods. Conceptually simple, but of little practical value, combustion of silane gives silicon dioxide. This reaction is analogous to the combustion of methane:

 

However the chemical vapor deposition of silicon dioxide onto crystal surface from silane had been used using nitrogen as a carrier gas at 200–500 °C.[64]

Chemical reactions

edit

Silicon dioxide is a relatively inert material (hence its widespread occurrence as a mineral). Silica is often used as inert containers for chemical reactions. At high temperatures, it is converted to silicon by reduction with carbon.

Fluorine reacts with silicon dioxide to form SiF4 and O2 whereas the other halogen gases (Cl2, Br2, I2) are unreactive.[15]

Most forms of silicon dioxide are attacked ("etched") by hydrofluoric acid (HF) to produce hexafluorosilicic acid:[12]

SiO2 + 6 HF → H2SiF6 + 2 H2O

Stishovite does not react to HF to any significant degree.[65] HF is used to remove or pattern silicon dioxide in the semiconductor industry.

Silicon dioxide acts as a Lux–Flood acid, being able to react with bases under certain conditions. As it does not contain any hydrogen, non-hydrated silica cannot directly act as a Brønsted–Lowry acid. While silicon dioxide is only poorly soluble in water at low or neutral pH (typically, 2 × 10−4 M for quartz up to 10−3 M for cryptocrystalline chalcedony), strong bases react with glass and easily dissolve it. Therefore, strong bases have to be stored in plastic bottles to avoid jamming the bottle cap, to preserve the integrity of the recipient, and to avoid undesirable contamination by silicate anions.[66]

Silicon dioxide dissolves in hot concentrated alkali or fused hydroxide, as described in this idealized equation:[15]

 

Silicon dioxide will neutralise basic metal oxides (e.g. sodium oxide, potassium oxide, lead(II) oxide, zinc oxide, or mixtures of oxides, forming silicates and glasses as the Si-O-Si bonds in silica are broken successively).[12] As an example the reaction of sodium oxide and SiO2 can produce sodium orthosilicate, sodium silicate, and glasses, dependent on the proportions of reactants:[15]

 
 
   .

Examples of such glasses have commercial significance, e.g. soda–lime glass, borosilicate glass, lead glass. In these glasses, silica is termed the network former or lattice former.[12] The reaction is also used in blast furnaces to remove sand impurities in the ore by neutralisation with calcium oxide, forming calcium silicate slag.

 
Bundle of optical fibres composed of high purity silica

Silicon dioxide reacts in heated reflux under dinitrogen with ethylene glycol and an alkali metal base to produce highly reactive, pentacoordinate silicates which provide access to a wide variety of new silicon compounds.[67] The silicates are essentially insoluble in all polar solvent except methanol.

Silicon dioxide reacts with elemental silicon at high temperatures to produce SiO:[12]

 

Water solubility

edit

The solubility of silicon dioxide in water strongly depends on its crystalline form and is three to four times higher for amorphous silica than quartz; as a function of temperature, it peaks around 340 °C (644 °F).[68] This property is used to grow single crystals of quartz in a hydrothermal process where natural quartz is dissolved in superheated water in a pressure vessel that is cooler at the top. Crystals of 0.5–1  kg can be grown for 1–2 months.[12] These crystals are a source of very pure quartz for use in electronic applications.[15] Above the critical temperature of water 647.096 K (373.946 °C; 705.103 °F) and a pressure of 22.064 megapascals (3,200.1 psi) or higher, water is a supercritical fluid and solubility is once again higher than at lower temperatures.[69]

Health effects

edit
 
Quartz sand (silica) as main raw material for commercial glass production

Silica ingested orally is essentially nontoxic, with an LD50 of 5000 mg/kg (5 g/kg).[22] A 2008 study following subjects for 15 years found that higher levels of silica in water appeared to decrease the risk of dementia. An increase of 10 mg/day of silica in drinking water was associated with a reduced risk of dementia of 11%.[70]

Inhaling finely divided crystalline silica dust can lead to silicosis, bronchitis, or lung cancer, as the dust becomes lodged in the lungs and continuously irritates the tissue, reducing lung capacities.[71] When fine silica particles are inhaled in large enough quantities (such as through occupational exposure), it increases the risk of systemic autoimmune diseases such as lupus[72] and rheumatoid arthritis compared to expected rates in the general population.[73]

Occupational hazard

edit

Silica is an occupational hazard for people who do sandblasting or work with powdered crystalline silica products. Amorphous silica, such as fumed silica, may cause irreversible lung damage in some cases but is not associated with the development of silicosis. Children, asthmatics of any age, those with allergies, and the elderly (all of whom have reduced lung capacity) can be affected in less time.[74]

Crystalline silica is an occupational hazard for those working with stone countertops because the process of cutting and installing the countertops creates large amounts of airborne silica.[75] Crystalline silica used in hydraulic fracturing presents a health hazard to workers.[34]

Pathophysiology

edit

In the body, crystalline silica particles do not dissolve over clinically relevant periods. Silica crystals inside the lungs can activate the NLRP3 inflammasome inside macrophages and dendritic cells and thereby result in production of interleukin, a highly pro-inflammatory cytokine in the immune system.[76][77][78]

Regulation

edit

Regulations restricting silica exposure 'with respect to the silicosis hazard' specify that they are concerned only with silica, which is both crystalline and dust-forming.[79][80][81][82][83][84]

In 2013, the U.S. Occupational Safety and Health Administration reduced the exposure limit to 50 μg/m3 of air. Prior to 2013, it had allowed 100 μg/m3 and in construction workers even 250 μg/m3.[34] In 2013, OSHA also required the "green completion" of fracked wells to reduce exposure to crystalline silica and restrict the exposure limit.[34]

Crystalline forms

edit

SiO2, more so than almost any material, exists in many crystalline forms. These forms are called polymorphs.

Crystalline forms of SiO2[12]
Form Crystal symmetry
Pearson symbol, group no.
ρ
(g/cm3)
Notes Structure
α-quartz rhombohedral (trigonal)
hP9, P3121 No.152[85]
2.648 Helical chains making individual single crystals optically active; α-quartz converts to β-quartz at 846 K  
β-quartz hexagonal
hP18, P6222, No. 180[86]
2.533 Closely related to α-quartz (with an Si-O-Si angle of 155°) and optically active; β-quartz converts to β-tridymite at 1140 K  
α-tridymite orthorhombic
oS24, C2221, No.20[87]
2.265 Metastable form under normal pressure  
β-tridymite hexagonal
hP12, P63/mmc, No. 194[87]
Closely related to α-tridymite; β-tridymite converts to β-cristobalite at 2010 K  
α-cristobalite tetragonal
tP12, P41212, No. 92[88]
2.334 Metastable form under normal pressure  
β-cristobalite cubic
cF104, Fd3m, No.227[89]
Closely related to α-cristobalite; melts at 1978 K  
keatite tetragonal
tP36, P41212, No. 92[90]
3.011 Si5O10, Si4O8, Si8O16 rings; synthesised from glassy silica and alkali at 600–900 K and 40–400 MPa  
moganite monoclinic
mS46, C2/c, No.15[91]
Si4O8 and Si6O12 rings  
coesite monoclinic
mS48, C2/c, No.15[92]
2.911 Si4O8 and Si8O16 rings; 900 K and 3–3.5 GPa  
stishovite tetragonal
tP6, P42/mnm, No.136[93]
4.287 One of the densest (together with seifertite) polymorphs of silica; rutile-like with 6-fold coordinated Si; 7.5–8.5 GPa  
seifertite orthorhombic
oP, Pbcn[94]
4.294 One of the densest (together with stishovite) polymorphs of silica; is produced at pressures above 40 GPa.[95]  
melanophlogite cubic (cP*, P4232, No.208)[7] or
tetragonal (P42/nbc)[96]
2.04 Si5O10, Si6O12 rings; mineral always found with hydrocarbons in interstitial spaces - a clathrasil (silica clathrate)[97]  
fibrous
W-silica[15]
orthorhombic
oI12, Ibam, No.72[98]
1.97 Like SiS2 consisting of edge-sharing chains, melts at ~1700 K  
2D silica[99] hexagonal Sheet-like bilayer structure  

Safety

edit

Inhaling finely divided crystalline silica can lead to severe inflammation of the lung tissue, silicosis, bronchitis, lung cancer, and systemic autoimmune diseases, such as lupus and rheumatoid arthritis. Inhalation of amorphous silicon dioxide, in high doses, leads to non-permanent short-term inflammation, where all effects heal.[100]

Other names

edit

This extended list enumerates synonyms for silicon dioxide; all of these values are from a single source; values in the source were presented capitalized.[101]

  • CAS 112945-52-5
  • Acitcel
  • Aerosil
  • Amorphous silica dust
  • Aquafil
  • CAB-O-GRIP II
  • CAB-O-SIL
  • CAB-O-SPERSE
  • Catalogue
  • Colloidal silica[102]
  • Colloidal silicon dioxide
  • Dicalite
  • DRI-DIE Insecticide 67
  • FLO-GARD
  • Fossil flour
  • Fumed silica
  • Fumed silicon dioxide
  • HI-SEL
  • LO-VEL
  • Ludox
  • Nalcoag
  • Nyacol
  • Santocel
  • Silica
  • Silica aerogel
  • Silica, amorphous
  • Silicic anhydride
  • Silikill
  • Synthetic amorphous silica
  • Vulkasil

See also

edit

References

edit
  1. ^ a b c d e Haynes WM, ed. (2011). CRC Handbook of Chemistry and Physics (92nd ed.). Boca Raton, FL: CRC Press. ISBN 1-4398-5511-0.
  2. ^ a b c NIOSH Pocket Guide to Chemical Hazards. "#0552". National Institute for Occupational Safety and Health (NIOSH).
  3. ^ a b NIOSH Pocket Guide to Chemical Hazards. "#0682". National Institute for Occupational Safety and Health (NIOSH).
  4. ^ a b Zumdahl, Steven S. (2009). Chemical Principles 6th Ed. Houghton Mifflin Company. p. A22. ISBN 978-0-618-94690-7.
  5. ^ Iler RK (1979). The Chemistry of Silica. New York: Wiley. ISBN 9780471024040.
  6. ^ a b Fernández LD, Lara E, Mitchell EA (2015). "Checklist, diversity and distribution of testate amoebae in Chile" (PDF). European Journal of Protistology. 51 (5): 409–24. doi:10.1016/j.ejop.2015.07.001. PMID 26340665. Archived (PDF) from the original on 2022-10-10.
  7. ^ a b Skinner BJ, Appleman DE (1963). "Melanophlogite, a cubic polymorph of silica" (PDF). Am. Mineral. 48: 854–867. Archived (PDF) from the original on 2022-10-10.
  8. ^ Douglas BE, Ho SM, eds. (2006), "Crystal Structures of Silica and Metal Silicates", Structure and Chemistry of Crystalline Solids, New York, NY: Springer, pp. 233–278, doi:10.1007/0-387-36687-3_10, ISBN 978-0-387-36687-6, retrieved 2023-10-08
  9. ^ Nekrashevich SS, Gritsenko VA (2014-02-01). "Electronic structure of silicon dioxide (a review)". Physics of the Solid State. 56 (2): 207–222. Bibcode:2014PhSS...56..207N. doi:10.1134/S106378341402022X. ISSN 1090-6460. S2CID 255234311.
  10. ^ N. C. Norman (1997). Periodicity and the s- and p-Block Elements. Oxford University Press. pp. 50–52, 65–67. ISBN 978-0-19-855961-0.
  11. ^ Unger KK, ed. (1979), Chapter 1 General chemistry of silica, Journal of Chromatography Library, vol. 16, Elsevier, pp. 1–14, doi:10.1016/s0301-4770(08)60805-2, ISBN 978-0-444-41683-4, retrieved 2023-09-12
  12. ^ a b c d e f g Holleman AF, Wiberg E (2001), Wiberg N (ed.), Inorganic Chemistry, translated by Eagleson M, Brewer W, San Diego/Berlin: Academic Press/De Gruyter, ISBN 0-12-352651-5
  13. ^ Cuff YH (1996). Ceramic Technology for Potters and Sculptors. Philadelphia: University of Pennsylvania. pp. 93–95. ISBN 9780812213775.
  14. ^ De La Rocha C, Conley DJ (2017). "Mystical Crystals of Silica". Silica Stories. Cham: Springer. pp. 50–55. doi:10.1007/978-3-319-54054-2_4. ISBN 9783319540542.
  15. ^ a b c d e f g h Greenwood NN, Earnshaw A (1984). Chemistry of the Elements. Oxford: Pergamon Press. pp. 393–99. ISBN 978-0-08-022057-4.
  16. ^ Wells AF (1984). Structural Inorganic Chemistry. Oxford Science Publications. ISBN 9780198553700.
  17. ^ Kirfel A, Krane HG, Blaha P, et al. (2001). "Electron-density distribution in stishovite, SiO2: a new high-energy synchrotron-radiation study". Acta Crystallographica Section A. 57 (6): 663–77. Bibcode:2001AcCrA..57..663K. doi:10.1107/S0108767301010698. PMID 11679696.
  18. ^ Scherzer J (1978). "Dealuminated faujasite-type structures with SiO2/Al2O3 ratios over 100". J. Catal. 54 (2): 285. doi:10.1016/0021-9517(78)90051-9.
  19. ^ Shell SM, Debenedetti PG, Panagiotopoulos AZ (2002). "Molecular structural order and anomalies in liquid silica" (PDF). Phys. Rev. E. 66 (1): 011202. arXiv:cond-mat/0203383. Bibcode:2002PhRvE..66a1202S. doi:10.1103/PhysRevE.66.011202. PMID 12241346. S2CID 6109212. Archived from the original (PDF) on 2016-06-04. Retrieved 2009-07-07.
  20. ^ Aksay IA, Pask JA, Davis RF (1979). "Densities of SiO2-Al2O3 Melts" (PDF). J. Am. Ceram. Soc. 62 (7–8): 332–336. doi:10.1111/j.1151-2916.1979.tb19071.x. Archived (PDF) from the original on 2022-10-10.
  21. ^ Jutzi P, Schubert U (2003). Silicon chemistry: from the atom to extended systems. Wiley-VCH. ISBN 9783527306473.
  22. ^ a b c d e Flörke OW, Graetsch HA, Brunk F, et al. (2018). "Silica". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a23_583.pub3. ISBN 978-3527306732.
  23. ^ Berslien E (2012). An Introduction to Forensic Geoscience. Wiley & Sons. p. 138. ISBN 9781405160544.
  24. ^ Massey FP, Ennos AR, Hartley SE (2006). "Silica in grasses as a defence against insect herbivores: Contrasting effects on folivores and a phloem feeder". J. Anim. Ecol. 75 (2): 595–603. Bibcode:2006JAnEc..75..595M. doi:10.1111/j.1365-2656.2006.01082.x. PMID 16638012.
  25. ^ Keeping MG, Kvedaras OL (2008). "Silicon as a plant defence against insect herbivory: Response to Massey, Ennos and Hartley". J. Anim. Ecol. 77 (3): 631–3. Bibcode:2008JAnEc..77..631K. doi:10.1111/j.1365-2656.2008.01380.x. PMID 18341561.
  26. ^ Zain MF, Islam MN, Mahmud F, Jamil M (2011). "Production of rice husk ash for use in concrete as a supplementary cementitious material". Construction and Building Materials. Composite Materials and Adhesive Bonding Technology. 25 (2): 798–805. doi:10.1016/j.conbuildmat.2010.07.003. ISSN 0950-0618.
  27. ^ Perry CC (2003). "Silicification: The Processes by Which Organisms Capture and Mineralize Silica". Reviews in Mineralogy and Geochemistry. 1 (54): 291–327. Bibcode:2003RvMG...54..291P. doi:10.2113/0540291.
  28. ^ Radini A (2024). "Archaeobotany: Plant Microfossils". In Nikita E, Rehren T (eds.). Encyclopedia of Archaeology (Second ed.). Oxford: Academic Press. pp. 698–707. doi:10.1016/b978-0-323-90799-6.00114-2. ISBN 978-0-323-91856-5. Retrieved 2024-06-20.
  29. ^ Neumann M, Wagner S, Noske R, Tiersch B, Strauch P (2010). "Morphology and Structure of Biomorphous Silica Isolated from Equisetum hyemale and Equisetum telmateia". Zeitschrift für Naturforschung B. 65 (9): 1113–1120. doi:10.1515/znb-2010-0910. ISSN 1865-7117.
  30. ^ Tubaña BS, Heckman JR (2015), Rodrigues FA, Datnoff LE (eds.), "Silicon in Soils and Plants", Silicon and Plant Diseases, Cham: Springer International Publishing, pp. 7–51, doi:10.1007/978-3-319-22930-0_2, ISBN 978-3-319-22929-4, retrieved 2024-07-19
  31. ^ Irzaman I, Yustaeni D, Aminullah A, Irmansyah I, Yuliarto B (2021-04-19). "Purity, Morphological, and Electrical Characterization of Silicon Dioxide from Cogon Grass (Imperata cylindrica) Using Different Ashing Temperatures". Egyptian Journal of Chemistry. 64 (8): 4143–4149. doi:10.21608/ejchem.2019.15430.1962. ISSN 2357-0245.
  32. ^ Uriz MJ, Turon X, Becerro MA, Agell G (2003). "Siliceous spicules and skeleton frameworks in sponges: Origin, diversity, ultrastructural patterns, and biological functions". Microscopy Research and Technique. 62 (4): 279–299. doi:10.1002/jemt.10395. ISSN 1059-910X. PMID 14534903.
  33. ^ Nevin CM (1925). Albany moulding sands of the Hudson Valley. University of the State of New York at Albany.
  34. ^ a b c d Greenhouse S (23 Aug 2013). "New Rules Would Cut Silica Dust Exposure". The New York Times. Retrieved 24 Aug 2013.
  35. ^ Ojovan MI (2004). "Glass formation in amorphous SiO2 as a percolation phase transition in a system of network defects". JETP Lett. 79 (12): 632–634. Bibcode:2004JETPL..79..632O. doi:10.1134/1.1790021. S2CID 124299526.
  36. ^ Stachurski ZH (2015). Fundamentals of Amorphous Solids: Structure and Properties. John Wiley & Sons. p. 176. ISBN 978-3-527-68219-5.
  37. ^ Advanced Inorganic Chemistry: Vollume II. Krishna Prakashan Media. p. 563.
  38. ^ Elliott SR (1991). "Medium-range structural order in covalent amorphous solids". Nature. 354 (6353): 445–452. Bibcode:1991Natur.354..445E. doi:10.1038/354445a0. S2CID 4344891.
  39. ^ Atkins PW, Overton T, Rourke J, et al., eds. (2010). Shriver & Atkins' inorganic chemistry (5th ed.). Oxford: Oxford University Press. p. 354. ISBN 9780199236176. OCLC 430678988.
  40. ^ a b "Cab-O-Sil Fumed Metal Oxides".
  41. ^ Cheraghian G, Wistuba MP, Kiani S, Barron AR, Behnood A (December 2021). "Rheological, physicochemical, and microstructural properties of asphalt binder modified by fumed silica nanoparticles". Scientific Reports. 11 (1): 11455. Bibcode:2021NatSR..1111455C. doi:10.1038/s41598-021-90620-w. PMC 8169902. PMID 34075083.
  42. ^ Barel AO, Paye M, Maibach HI (2014). Handbook of Cosmetic Science and Technology (4th ed.). CRC Press. p. 444. ISBN 9781842145654. These soft-focus pigments, mainly composed of polymers, micas and talcs covered with rough or spherical particles of small diameters, such as silica or titanium dioxide, are used to optically reduce the appearance of wrinkles. These effects are obtained by optimizing outlines of wrinkles and reducing the difference of brightness due to diffuse reflection.
  43. ^ Barel AO, Paye M, Maibach HI (2014). Handbook of Cosmetic Science and Technology (4th ed.). CRC Press. p. 442. ISBN 9781842145654. The silica is a multiporous ingredient, which absorbs the oil and sebum.
  44. ^ Gardner JS (1882). "On the Causes of Elevation and Subsidence". Geological Magazine. 9 (10): 479–480. Bibcode:1882GeoM....9..479G. doi:10.1017/S0016756800172474. ISSN 0016-7568.
  45. ^ Mann A (1917). The Economic Importance of the Diatoms. Washington DC, United States of America: Smithsonian.
  46. ^ Bassett RK (2007). To the Digital Age: Research Labs, Start-up Companies, and the Rise of MOS Technology. Johns Hopkins University Press. pp. 22–23. ISBN 9780801886393.
  47. ^ a b Lécuyer C, Brock DC (2010). Makers of the Microchip: A Documentary History of Fairchild Semiconductor. MIT Press. p. 111. ISBN 9780262294324.
  48. ^ a b Saxena A (2009). Invention of integrated circuits: untold important facts. International series on advances in solid state electronics and technology. World Scientific. pp. 96–97. ISBN 9789812814456.
  49. ^ a b c "Martin Atalla in Inventors Hall of Fame, 2009". Retrieved 21 June 2013.
  50. ^ a b Black LE (2016). New Perspectives on Surface Passivation: Understanding the Si-Al2O3 Interface. Springer. p. 17. ISBN 9783319325217.
  51. ^ a b "Dawon Kahng". National Inventors Hall of Fame. Retrieved 27 June 2019.
  52. ^ Liu G, Liu Y, Zhao X (2017). "The Influence of Spherical Nano-SiO 2 Content on the Thermal Protection Performance of Thermal Insulation Ablation Resistant Coated Fabrics". Journal of Nanomaterials. 2017: 1–11. doi:10.1155/2017/2176795. ISSN 1687-4110.
  53. ^ Goodwin W, Linacre A, Hadi S (2007). An Introduction to Forensic Genetics. Wiley & Sons. p. 29. ISBN 9780470010259.
  54. ^ Calderone J (20 Aug 2015). "This cloud-like, futuristic material has been sneaking its way into your life since 1931". Business Insider. Retrieved 11 Feb 2019.
  55. ^ Götze J, Möckel R, eds. (2012). Quartz: Deposits, Mineralogy and Analytics. Springer Geology. Berlin, Heidelberg: Springer Berlin Heidelberg. Bibcode:2012qdma.book.....G. doi:10.1007/978-3-642-22161-3. ISBN 978-3-642-22160-6.
  56. ^ Pan X, Li S, Li Y, Guo P, Zhao X, Cai Y (2022). "Resource, characteristic, purification and application of quartz: a review". Minerals Engineering. 183: 107600. Bibcode:2022MiEng.18307600P. doi:10.1016/j.mineng.2022.107600.
  57. ^ Doering R, Nishi Y, eds. (2007). Handbook of Semiconductor Manufacturing Technology. CRC Press. ISBN 9781574446753.
  58. ^ Lee S (2006). Encyclopedia of chemical processing. CRC Press. ISBN 9780824755638.
  59. ^ Morgan DV, Board K (1991). An Introduction To Semiconductor Microtechnology (2nd ed.). Chichester, West Sussex, England: John Wiley & Sons. p. 72. ISBN 9780471924784.
  60. ^ Riordan M (2007). "The Silicon Dioxide Solution: How physicist Jean Hoerni built the bridge from the transistor to the integrated circuit". IEEE Spectrum. Retrieved 11 Feb 2019.
  61. ^ Chrystie RS, Ebertz FL, Dreier T, Schulz C (2019-01-28). "Absolute SiO concentration imaging in low-pressure nanoparticle-synthesis flames via laser-induced fluorescence". Applied Physics B. 125 (2): 29. Bibcode:2019ApPhB.125...29C. doi:10.1007/s00340-019-7137-8. ISSN 1432-0649. S2CID 127735545.
  62. ^ Romero-Jaime AK, Acosta-Enríquez MC, Vargas-Hernández D, Tánori-Córdova JC, Pineda León HA, Castillo SJ (August 2021). "Synthesis and characterization of silica–lead sulfide core–shell nanospheres for applications in optoelectronic devices". Journal of Materials Science: Materials in Electronics. 32 (16): 21425–21431. doi:10.1007/s10854-021-06648-1. ISSN 0957-4522. S2CID 236182027.
  63. ^ Nandiyanto AB, Kim SG, Iskandar F, et al. (2009). "Synthesis of spherical mesoporous silica nanoparticles with nanometer-size controllable pores and outer diameters". Microporous and Mesoporous Materials. 120 (3): 447–453. Bibcode:2009MicMM.120..447N. doi:10.1016/j.micromeso.2008.12.019.
  64. ^ Morgan DV, Board K (1991). An Introduction To Semiconductor Microtechnology (2nd ed.). Chichester, West Sussex, England: John Wiley & Sons. p. 27. ISBN 9780471924784.
  65. ^ Fleischer M (1962). "New mineral names" (PDF). American Mineralogist. 47 (2). Mineralogical Society of America: 172–174. Archived (PDF) from the original on 2011-07-22.
  66. ^ Rodgers GE (2011). Descriptive Inorganic, Coordination, and Solid State Chemistry. Cengage Learning. pp. 421–2. ISBN 9781133172482.
  67. ^ Laine RM, Blohowiak KY, Robinson TR, Hoppe ML, Nardi P, Kampf J, Uhm J (17 October 1991). "Synthesis of pentacoordinate silicon complexes from SiO2" (PDF). Nature. 353 (6345): 642–644. Bibcode:1991Natur.353..642L. doi:10.1038/353642a0. hdl:2027.42/62810. S2CID 4310228. Archived (PDF) from the original on 2017-08-19.
  68. ^ Fournier RO, Rowe JJ (1977). "The solubility of amorphous silica in water at high temperatures and high pressures" (PDF). Am. Mineral. 62: 1052–1056. Archived (PDF) from the original on 2022-10-10.
  69. ^ Okamoto A (2019). "Formation of silica particles from supercritical fluids and its impacts on the hydrological properties in the crust". EGU General Assembly Conference Abstracts: 4614. Bibcode:2019EGUGA..21.4614O.
  70. ^ Rondeau V, Jacqmin-Gadda H, Commenges D, et al. (2008). "Aluminum and Silica in Drinking Water and the Risk of Alzheimer's Disease or Cognitive Decline: Findings from 15-Year Follow-up of the PAQUID Cohort". American Journal of Epidemiology. 169 (4): 489–96. doi:10.1093/aje/kwn348. PMC 2809081. PMID 19064650.
  71. ^ "Work Safely with Silica". CPWR - The Center for Construction Research and Training. Retrieved 11 Feb 2019.
  72. ^ "Action Plan for Lupus Research". National Institute of Arthritis and Musculoskeletal and Skin Diseases. National Institutes of Health. 2017. Retrieved 11 Feb 2019.
  73. ^ Meyer A, Sandler DP, Beane Freeman LE, et al. (2017). "Pesticide Exposure and Risk of Rheumatoid Arthritis among Licensed Male Pesticide Applicators in the Agricultural Health Study". Environmental Health Perspectives. 125 (7): 077010-1–077010-7. doi:10.1289/EHP1013. PMC 5744649. PMID 28718769.
  74. ^ Reuzel PG, Bruijntjes JP, Feron VJ, et al. (1991). "Subchronic inhalation toxicity of amorphous silica and quartz dust in rats". Food Chem. Toxicol. 29 (5): 341–54. doi:10.1016/0278-6915(91)90205-L. PMID 1648030.
  75. ^ "Worker Exposure to Silica during Countertop Manufacturing, Finishing and Installation" (PDF). National Institute for Occupational Safety and Health and Occupational Safety and Health Administration. 2015. Archived (PDF) from the original on 2022-10-10. Retrieved 26 Feb 2015.
  76. ^ Hornung V, Bauernfeind F, Halle A, et al. (2008). "Silica crystals and aluminum salts activate the NALP3 inflammasome through phagosomal destabilization". Nat. Immunol. 9 (8): 847–856. doi:10.1038/ni.1631. PMC 2834784. PMID 18604214.
  77. ^ Merchant JA, ed. (1986). Occupational Respiratory Diseases (PDF). Cincinnati, OH: US Department of Health and Human Services, NIOSH. doi:10.26616/NIOSHPUB86102. hdl:2027/uc1.31210023588922. DHHS (NIOSH) Publication Number 86-102.
  78. ^ NIOSH (2002) Hazard Review, Health Effects of Occupational Exposure to Respirable Crystalline Silica. Cincinnati, OH: U.S. Department of Health and Human Services, U.S. Public Health Service, Centers for Disease Control, National Institute for Occupational Safety and Health, DHHS (NIOSH) Publication No. 2002-129.
  79. ^ "Crystalline Factsheet" (PDF). Archived from the original (PDF) on 22 December 2017. Retrieved 3 August 2017.
  80. ^ "Silica, Crystalline". Retrieved 3 August 2017.
  81. ^ "Frequently Asked Questions". Retrieved 3 August 2017.
  82. ^ "If It's Silica, It's Not Just Dust!" (PDF). Archived (PDF) from the original on 2022-10-10. Retrieved 3 August 2017.
  83. ^ "What you should know about crystalline silica, silicosis, and Oregon OSHA silica rules" (PDF). Archived (PDF) from the original on 2022-10-10. Retrieved 3 August 2017.
  84. ^ Szymendera SD (January 16, 2018). Respirable Crystalline Silica in the Workplace: New Occupational Safety and Health Administration (OSHA) Standards (PDF). Washington, DC: Congressional Research Service. Archived (PDF) from the original on 2022-10-10. Retrieved 27 January 2018.
  85. ^ Lager G. A., Jorgensen J. D., Rotella F.J. (1982). "Crystal structure and thermal expansion of a-quartz SiO2 at low temperature". Journal of Applied Physics. 53 (10): 6751–6756. Bibcode:1982JAP....53.6751L. doi:10.1063/1.330062.
  86. ^ Wright AF, Lehmann MS (1981). "The structure of quartz at 25 and 590 °C determined by neutron diffraction". Journal of Solid State Chemistry. 36 (3): 371–80. Bibcode:1981JSSCh..36..371W. doi:10.1016/0022-4596(81)90449-7.
  87. ^ a b Kihara K, Matsumoto T, Imamura M (1986). "Structural change of orthorhombic-Itridymite with temperature: A study based on second-order thermal-vibrational parameters". Zeitschrift für Kristallographie. 177 (1–2): 27–38. Bibcode:1986ZK....177...27K. doi:10.1524/zkri.1986.177.1-2.27.
  88. ^ Downs R. T., Palmer D. C. (1994). "The pressure behavior of a cristobalite" (PDF). American Mineralogist. 79: 9–14. Archived (PDF) from the original on 2022-10-10.
  89. ^ Wright AF, Leadbetter AJ (1975). "The structures of the β-cristobalite phases of SiO2 and AlPO4". Philosophical Magazine. 31 (6): 1391–401. Bibcode:1975PMag...31.1391W. doi:10.1080/00318087508228690.
  90. ^ Shropshire J, Keat PP, Vaughan PA (1959). "The crystal structure of keatite, a new form of silica". Zeitschrift für Kristallographie. 112 (1–6): 409–13. Bibcode:1959ZK....112..409S. doi:10.1524/zkri.1959.112.1-6.409.
  91. ^ Miehe G, Graetsch H (1992). "Crystal structure of moganite: a new structure type for silica". European Journal of Mineralogy. 4 (4): 693–706. Bibcode:1992EJMin...4..693M. doi:10.1127/ejm/4/4/0693.
  92. ^ Levien L., Prewitt C. T. (1981). "High-pressure crystal structure and compressibility of coesite" (PDF). American Mineralogist. 66: 324–333. Archived (PDF) from the original on 2022-10-10.
  93. ^ Smyth J. R., Swope R. J., Pawley A. R. (1995). "H in rutile-type compounds: II. Crystal chemistry of Al substitution in H-bearing stishovite" (PDF). American Mineralogist. 80 (5–6): 454–456. Bibcode:1995AmMin..80..454S. doi:10.2138/am-1995-5-605. S2CID 196903109. Archived (PDF) from the original on 2022-10-10.
  94. ^ Dera P., Prewitt C. T., Boctor N. Z., Hemley R. J. (2002). "Characterization of a high-pressure phase of silica from the Martian meteorite Shergotty". American Mineralogist. 87 (7): 1018. Bibcode:2002AmMin..87.1018D. doi:10.2138/am-2002-0728. S2CID 129400258.
  95. ^ Seifertite. Mindat.org.
  96. ^ Nakagawa T., Kihara K., Harada K. (2001). "The crystal structure of low melanophlogite". American Mineralogist. 86 (11–12): 1506. Bibcode:2001AmMin..86.1506N. doi:10.2138/am-2001-11-1219. S2CID 53525827.
  97. ^ Rosemarie Szostak (1998). Molecular sieves: Principles of Synthesis and Identification. Springer. ISBN 978-0-7514-0480-7.
  98. ^ Weiss A, Weiss A (1954). "Über Siliciumchalkogenide. VI. Zur Kenntnis der faserigen Siliciumdioxyd-Modifikation". Zeitschrift für Anorganische und Allgemeine Chemie. 276 (1–2): 95–112. doi:10.1002/zaac.19542760110.
  99. ^ Björkman T, Kurasch S, Lehtinen O, Kotakoski J, Yazyev OV, Srivastava A, Skakalova V, Smet JH, Kaiser U, Krasheninnikov AV (2013). "Defects in bilayer silica and graphene: common trends in diverse hexagonal two-dimensional systems". Scientific Reports. 3: 3482. Bibcode:2013NatSR...3E3482B. doi:10.1038/srep03482. PMC 3863822. PMID 24336488.
  100. ^ Johnston CJ, Driscoll KE, Finkelstein JN, et al. (2000). "Pulmonary Chemokine and Mutagenic Responses in Rats after Subchronic Inhalation of Amorphous and Crystalline Silica". Toxicological Sciences. 56 (2): 405–413. doi:10.1093/toxsci/56.2.405. PMID 10911000.
  101. ^ Lewis GR (1999). 1001 chemicals in everyday products (2nd ed.). John Wiley & Sons (Wiley-Interscience). pp. 250–1. ISBN 0-471-29212-5 – via Internet Archive.
  102. ^ Bergna HE, ed. (1994-05-05). The Colloid Chemistry of Silica. Advances in Chemistry. Vol. 234. Washington DC: American Chemical Society. pp. 1–47. doi:10.1021/ba-1994-0234.ch001. ISBN 978-0-8412-2103-1.
edit