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Silicon dioxide (SiO2) is the most common silicon compound and a major constituent of the Earth’s crust.

 

Properties and Applications

Silicon dioxide is a very hard substance that is resistant against chemicals and alteration. Both crystalline and amorphous SiO2 are nearly insoluble in water and in acids. In aqueous suspensions, however, the very fine-grained forms of the amorphous type slowly transform into silicic acid SiO2 x n H2O. At 25 °C and a pH-value of 7 (neutral), approximately 0,12 g SiO2 per liter water (120 ppm) dissolve that way [6,7]. The dissolution rate of amorphous SiO2 is about 10 times higher than that of quartz. Particularly amorphous SiO2 can be dissolved by aqueous alkaline substances. Being resistant against other acids, SiO2 corrodes when exposed to hydrofluoric acid.

 

Natural silicon dioxide is an important base material for the glass industry, the optical industry and building industry. Quartz glasses provide the basis for manufacturing lenses and other optical components as well as temperature-resistant equipment for the chemical industry. Different kinds of SiO2 are used for manufacturing concrete and other building materials. In addition, SiO2 are used as filters and desiccants.

 

In addition to Carbon Black nanostructured silica is used in new rolling-resistance tires as a filler. © B.Mathes, Dechema.In addition to Carbon Black nanostructured silica is used in new rolling-resistance tires as a filler. © B.Mathes, Dechema.

Synthetic amorphous SiO2 are used as fillers in plastics, rubber, dyes, and adhesives and serve as adsorbents or trickling agents. They improve the hardness and scratch resistance of surface coatings and varnishes. Although SiO2 has a lower hardness than aluminum oxide, which is used alternatively, clear varnishes that contain nanostructured SiO2 have a much better transparency.

 

Nano-SiO2 is used increasingly for tire manufacturing. Adding amorphous SiO2 as fillers in addition to Carbon Black, the tire roll resistance is reduced, and gasoline consumption decreases by up to five percent. Since CO2 emissions are reduced that way, this is not only easy on the wallet but also on the environment [5].

 

Amorphous silicon dioxides have been used for more than four decades as food additives (E551). They can be added to certain powdery foods such as table salt, seasonings, dietary supplements, and dry foods [3] to avoid clogging. Moreover, they are permitted for use as carrier substances in emulsifying agents, colorings, and flavors [9]. According to the EU Rules on Organic Farming[11], SiO2 additives are also approved for use in biological food. Since silicon dioxide can neither be absorbed nor salvaged by the human organism, it is excreted in its unchanged form. Amorphous SiO2 particles have been approved for use as food additives since they were first tested more than 40 years ago. Since the particle size and structure have remained unchanged, these substances are not considered products of modern nanotechnology [4].

 

Highly disperse (nanoscale) amorphous SiO2 are also contained in diverse pharmaceutical products such as tablets, suppositories, gels, and creams. The properties of the approved additives are laid down in the European Pharmacopoeia [10].

Moreover, amorphous silicon dioxide nanoparticles are used as water repellents for cotton in the textile industry and as abrasives in the electronics industry[8].

 

Silicon dioxid is not self-inflammable as nanometer-sized powder. Also as a mixture with air (dust) under the influence of an ignition source, it is not inflammable, so there is no possibility of a dust explosion.

 

Occurrence and Production

Image of an Opal. © K. Luginsland, TECHNOSEUM Mannheim.Image of an Opal. © K. Luginsland, TECHNOSEUM Mannheim.

It occurs in nature in the crystalline (mostly quartz) and amorphous forms. Being a major constituent of sand, it is found in numerous types of rock and occurs, in addition, in precious stones and gemstones such as rock crystal.

The so-called amorphous non-crystalline silicon dioxides may be of biological origin or are formed by nature whenever rock is subjected to high temperatures (volcanoes, meteorite impacts, lightning strokes, geysers). Opals, which are very popular due to their ”opalescent“ colors, are an amorphous form of SiO2.

 

High quantities of amorphous SiO2 are produced at a large scale through precipitation or in oxyhydrogen flames. The latter product is often referred to as pyrogenic SiO2 or pyrogenic silicic acid. Pyrogenic SiO2 occurs as powder that consists of primary particles sized 5-50 nm and forms solid aggregates above 100 nm (150-200 nm). The powders are characterized by high specific surface areas (above 50 m²/g).

 

 

Literature arrow down

  1. Roempp Online (DE): Silizium (last access date: Jun 2010).
  2. Wikipedia (EN): Silicon Dioxide  (last access date: Jun 2010).
  3. Zusatzstoffe-online.de: Siliziumdioxid (last access date: Jun 2010).
  4. NanoTrust Dossier No.004en (May 2008). Nanoparticles and nanostructured materials in the food industry, NanoTrust, Institute of Technology Assessment (ITA), Vienna.
  5. Hessen-Nanotech NEWS 4/2006. Nano-Produktion – Herstellung von und mit Nanotechnologie, Band 9, 01.09.2006.
  6. Amjad, Z (1998). Water soluble polymers: solution properties and applications, Kluwer Academic Publishers, New York, ISBN 0-306-45931-0.
  7. Iler, RK (1979). The Chemistry of Silica: Solubility, Polymerization, Colloid and Surface Properties and Biochemistry of Silica, John Wiley Sons, ISBN 978-0471024040.
  8. Som, C et al. (Mar 2010). Nanomaterialien in Textilien: Umwelt-, Gesundheits- und Sicherheits-Aspekte, Fokus: synthetische Nanopartikel. Empa und TVS Textilverband Schweiz, St. Gallen 2010. (in German).
  9. Zusatzstoff-Zulassungsverordnung (ZZulV) (1998). Verordnung über die Zulassung von Zusatzstoffen zu Lebensmitteln zu technologischen Zwecken. gesetze-im-internet.de (last access date: Mar 2010). (in German)
  10. Europäisches Arzneibuch (Pharmacopoea Europaea) (2008), 6. Ausgabe, Grundwerk, Deutscher Apotherker Verlag Stuttgart. ISBN 978-3769253832. (in German).
  11. European Council Regulation (EC) No 834/2007 (28.06.2007). On organic production and labelling of organic products and repealing Regulation (EEC) No 2092/91.

Current Research

Graphene interlayer © bonninturina / fotolia.com

Information on the sponsorship programmes of the German Federal Ministry of Education and Research on nanotechnologies for humans and the environment.

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Knowledge Base

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A database with important and generally understandable aspects on health and environment of applied nanomaterials as well as facts on the safety of manufactured nanomaterials.

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Nano Basics

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The chapters on release, exposure, uptake and behavior of nanomaterials in the human body and in the environment as well as the risk assessment will give you a first overview.

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Current Events

Mon Oct 05 @ 8:00AM - 05:00PM
Nanosafety2020
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Industrial Technologies 2020
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NanoSafety Cluster (NSC) Day @ NanoSAFE 2020
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Spotlight Research

In September we would like to present a paper of the BMBF project Fe-Nanosit. The project dealt with the use of iron-containing nanomaterials in groundwater and wastewater remediation. A comprehensive assessment and weighing of benefits and possible environmental risks resulting from the application is now presented by the project partners in this paper.

 

 

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