What are the advantages of SiO2 nanoparticles?

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Silicon dioxide (SiO2) is a compound of silicon and oxygen, commonly called silica and the elements are linked by the covalent bond. It is one of the components of the sand and can be found naturally in Quartz. It is usually white or colorless and is not soluble in water or ethanol. 

By associating with minerals, it forms the silicate family. Silicon dioxide (SiO2) has several industrial applications such as an additive in the food industry. Its function is to act as an anti-binder, anti-foaming agent, viscosity controller, desiccant, beverage clarifier and as an excipient of medications and vitamins. Due to its insolubility in water, silica has little biological availability and is not considered a source of silicon. Silicon found in other more soluble forms contributes to the formation and maintenance of bones and cartilage. Meet Nanografi's high purity silicon dioxide (SiO2) products and experience quality in many application areas.

Properties of Silicon Dioxide (SiO2) Nano Powder

Silicon dioxide is a solid and colorless crystalline substance. Silicon dioxide does not react with water and is resistant to acids. The molecular formula of the substance is SiO2. Silicon oxide, a member of the group of acidic glass-forming oxides, interacts with increasing temperature with alkalis and basic oxides, soluble in hydrofluoric acid, tends to form a supersonic fusion, that is, glass is an excellent dielectric. The main properties are stated below:

• SiO2 Nanoparticles is transparent and its density is kg/m3.

• The molar mass of SiO2 is 60. g/mol.

• The melting point is K, whereas the boiling point is K.

• Its crystal structure is Quartz, cristobalite or tridymite.

Figure 1. Structure of Silicon Dioxide (SiO2)

Applications of Silicon Dioxide (SiO2) Nano Powder

Silica (SiO2) nano powder is used to make flat glass, glass products, molten sand, cement, fiberglass, ceramic enamel, sandblasting for antioxidants, filter sand, flux, refractory and light concrete. Silicon dioxide (SiO2) Nanoparticles is widely used in many industrial products. Rare crystals in nature can be used to create important parts of the electronics, optical instruments and crafts industry. 

Silicon dioxide (SiO2) nano powder is an important raw material for the manufacture of optical fibers. Generally, pure quartz can be used to make quartz glass. The coefficient of expansion of quartz glass is very small. It is equivalent to 1/18 of ordinary glass. It can withstand temperature change and acid resistance is good. Therefore, quartz glass is often used to make chemical instruments resistant to high temperatures. Quartz sand is often used as a glass material and as a building material.

SiO2 Nanoparticles as Adhesive and Sealer

Silica (SiO2) nano powder is the preferred material in the adhesive and sealant field. Adding it to the sealant can quickly form a net structure, inhibit colloidal liquid, increases speed, improves the effect of bonding, and because the particles are small, the sealing of the adhesive increases.

Moreover, due to the special development of hydrophobic silicon dioxide, structural adhesives belonging to advanced technologies have been produced. These structural adhesives allow the joining of different materials such as steel, aluminum, magnesium, and plastic.

Numerous processes can benefit from the technical advantages and improvements that can be made with the proper selection of dioxides that have been specially developed for the special adhesives and sealants industry. Silicon dioxide (SiO2) nano powder not only improves the mechanical and rheological properties but also acts as a counter to the solution of agents that improve the storage and processing stability of adhesives and sealants.

Silicon dioxide (SiO2) is a commonly used nanomaterial in nanostructured epoxy adhesives. For in-depth information about epoxy adhesives, read our blog.

SiO2 Nanoparticles in Material Packing

Silicon dioxide (SiO2) Nanoparticles has a three-dimensional network structure and a large specific surface area. They show great activity and can form a mesh structure when the paint dries, it increases the strength and finish of the coating and improves the suspended pigment of the paint which do not fade for a long time.

SiO2 Nanoparticles in Textile Industry

Silicon (SiO2) nano powder has played an important role in functional textiles, at present, it has been used to prevent ultraviolet and works as an anti-aging and anti-bacterial deodorant. For example, the appropriate proportion of Silicon dioxide (SiO2)Nanoparticles is an important additive in resistance to ultraviolet radiation fiber.

If you are curious about the use and future of nanotechnology in the textile industry, read our blog now.

SiO2 Nanoparticles in Catalysis

Due to its large specific surface area, high porosity and good surface activity, Silicon dioxide (SiO2)nano powder has potential applications in the catalysis. Silicon dioxide (SiO2)nano powder works as a catalyst carrier. It shows the unique response performance for many sensitive reactions.

SiO2 Nanoparticles in Bactericide Field

Silica (SiO2)nano powder is used as a carrier in the preparation of fungicides, in which the antibacterial ion can be adsorbed and achieve the objective of sterilization. The application is used for the manufacture of items such as the refrigerator case, the computer keyboard. etc.

SiO2 Nanoparticles as Lubricating Oil Additives

Silicon dioxide (SiO2)Nanoparticles as lubricating oil additives show the excellent anti-wear property. In the field of lubricating oil additives, the particles of Silicon dioxide (SiO2) nano powder has hydroxyl and unsaturated bond and can form a solid chemical adsorption film and protect the metallic surface to significantly improve the friction performance of the lubricating oil.

To learn abot the silicon wafers and its applications, you can visit our blog page.

SiO2 Nanoparticles as Reinforcing Agent

Silicon dioxide (SiO2)Nanoparticles can replace carbon black as a reinforcing agent. It is anti-aging and changes color in rubber, it can produce colorful adhesive on the side of the tire.

SiO2 Nanoparticles&#; Biomedical Applications

Silica (SiO2)Nanoparticles may be used in cellular functions. Silicon dioxide (SiO2)nano powder has good biocompatibility and, therefore, are widely used as biological carriers. It has been found that Silicon dioxide (SiO2)nano powder interfere with the passage of Wnt signaling, which affects biological processes such as adipocyte differentiation, cancer cell migration and the development of zebrafish embryos. Silica (SiO2)Nanoparticles can cause Wnt signaling molecules to access the lysosome and degradation, and other molecules of Wnt signaling is not affected.

SiO2 Nanoparticles in Pharmaceutical Industry

Silica (SiO2)nano powder has an absolute necessity in the pharmaceutical industry. Silicon dioxide has become one of the most important and frequently used pharmaceutical excipients. The improvement of the flow properties of the materials necessary for the modern manufacture of tablets and capsules is nothing more than an example of the advantages obtained by the use of Silicon dioxide (SiO2)nano powder.

Some of the advantages and benefits of Silicon dioxide (SiO2)Nanoparticles for the pharmaceutical industry are solid forms of drugs, semi-solid forms of drugs, liquid forms of drugs, HD Pharma grade and Pharmacopoeia monographs.

If you want to learn more, please visit our website Hebei Silicon Research Electronic Materials Co., L.

SiO2 Nanoparticles in Paints and Inks

Silicon dioxide (SiO2)nano powder is mainly used in paints and coatings to control rheological characteristics, as a thixotropic agent, as opposed to the agent solution and to aid in the prevention of oxidation and Corrosion, this product should be added in concentrations of 0.5% - 2%.

Use of SiO2 Nanoparticles in Ceramic

It is a glass former. It is incorporated into the glaze as ground quartz. It is part of feldspars, clays, as a soluble source in the form of sodium silicate, it is found in all frits as well as in ashes especially rice or reeds. It has little influence on colors, except chrome and nickel reds. Increases opacity in glazes is rich in zinc and borax.

Additionally, research has highlighted that graphene is one of the best materials in ceramic coatings. Read our blog post for more information.

SiO2 Nanoparticles in Agriculture 

In agriculture, Silica (SiO2) Nanoparticles is used for seed treatment, can make vegetables, cabbage, tomatoes, yellow, cotton, corn, wheat, and increases the yield. Silicon dioxide (SiO2)nano powder can be used in herbicides and pesticides.

Silicon Dioxide (SiO2) Nanoparticles in Food Industry

In the food industry, food packaging bags that add Silicon dioxide (SiO2)nano powder keeps fruits and vegetables fresh. It is also used as anticoagulant, antifoam, thickener, auxiliary filter and clarifier in the food industry. The hygienic standard for the use of food additives stipulates that it can be used in egg powder, powdered sugar, powdered milk, cocoa powder, cocoa butter, vegetable powder, instant coffee, powder of soup, etc. The maximum amount of use is 15 g/kg.

Products that dissolve in water sometimes show a delay in getting wet or create lumps when removed. A further advantage of the adhesion of a food-grade hydrophilic Silica is that it improves wettability and even helps to prevent lumps from forming.

This is because silicon dust is enveloping, thus acting as a holder of space between the individual and the dust particles. In the water spaces, silicon dioxide provides good retention of colored powders and high transparency once it is raised in the water.

Thus, the addition of silicon dioxide helps prevent agglomeration, allowing powder producers to permanently offer a high-quality product worldwide, therefore, food products treated with silicon dioxide show stability and long storage.

Moreover, Silica is added in powdered foods and other supplements so that other ingredients bind together; For example, food manufacturers add silicon dioxide to salt and various species to keep substances dry, as an anti-caking agent, and to make processed foods tastier.

It also prevents the accumulation of some toxins in the body, such as aluminum and other heavy metals, which can prevent some problems that arise, as well as diseases when there is an acidic environment in many organs; the brain is one of them, which needs a good natural dosage to work properly over the years. Obviously, silicon dioxide is important to keep the musculoskeletal system healthy, especially during periods of training, where an extra agent is required to mineralize muscle collagen and bone system.

When the nails are brittle, a silicon dioxide supplement may be enough to recover them and keep them healthy. Taking silicon dioxide as a support agent for joint maintenance can be relatively useful. An investigation showed that by supplementing the diet with SiO2 ­as compared to other protective agents of the joints, this compound shows its power by keeping the entire system stronger in the face of hard training, in addition to helping to have a much more pronounced mental approach.

Conclusion

Silicon dioxide (SiO2) nanoparticles is a compound of silicon and oxygen, commonly called silica. It is one of the components of the sand. In nature, it occurs naturally as quartz. This spatially composed compound in a three-dimensional (crystallized) network forms quartz and all its varieties. If it is in an amorphous state it constitutes the opal and usually includes a high percentage of water. Silica (SiO2) nano powder has countless applications in a variety of sectors. It is used for the manufacturing of glass, quartz glass, soluble glass, optical fiber, important components of the electronics industry, optical instruments, crafts, and refractory materials. Moreover, it can act as reinforcing agent, adhesive, sealer and much more. It can be found naturally in Quartz. In fact, you will find its applications everywhere!

To improve the quality and performance of your projects and research with Nanografi's advanced materials, contact us.

References

Explained: Silicon Wafers and Its Applications - Nanografi Nano Technology. (n.d.). Retrieved January 29, , from https://nanografi.com/blog/explained-silicon-wafers-and-its-applications/

How Graphene is Better than Ceramic Coatings? - Nanografi Nano Technology. (n.d.). Retrieved January 29, , from https://nanografi.com/blog/how-graphene-is-better-than-ceramic-coatings/

Nanostructured Epoxy Adhesives - Nanografi Nano Technology. (n.d.). Retrieved January 29, , from https://nanografi.com/blog/nanostructured-epoxy-adhesives/

Silicon Dioxide, Diamond & Graphite (GCSE Chemistry) - Study Mind. (n.d.). Retrieved January 29, , from https://studymind.co.uk/notes/silicon-dioxide-diamond-graphite/

Use of Nanotechnology in Textile Industry and Its future - Nanografi Nano Technology. (n.d.). Retrieved January 29, , from https://nanografi.com/blog/use-of-nanotechnology-in-textile-industry-and-its-future/

Silica nanoparticles have a variety of interesting properties and thus a wide array of applications. They are strong, abrasive materials that can be used to polish silicon wafers. They are effective at reducing friction and as a result, are used to coat waxed floors and even railroad tracks. Their absorptive properties make them useful in papermaking as a drainage aid. They can serve as a binding agent in the manufacture of rubber, plastics, and concrete. Most notably, they are stable and non-toxic materials with innumerable applications in biomedicine.

Silica is an important component of an array of nanomaterial heterostructures with a wide range of interesting applications. Just a small sampling of these applications are described below.

Nanomedicine

Inorganic nanoparticles are useful for in vivo cell tracking due to their small sizes, high cellular uptake, and impedance mismatch with cells. A recent publication describes the use of NanoXact Silica Nanospheres as an ultrasound contrast agent to facilitate stem cell tracking in mice. The steps for cell labeling and nanoparticle integration are outlined in the report, using silica as a model system.

Mesoporous silica nanoparticles (MSNs) and hollow silica nanoparticles (HSNs) have garnered considerable attention for targeted drug delivery due to their uniquely large surface areas, easy surface modification, biocompatibility. The porous structures and surfaces can be engineered for targeting tissues and cells with unprecedented specificity and control. For more general information about nanomedicine, go to our course on Nanobiotechnology.

Catalysis

The pores and surface chemistries of mesoporous and hollow silica nanoparticles provide ideal sites for executing highly specific chemical transformations, offering increased efficiency and enhanced selectivity over other catalytic systems. The internal pores of these structures can be functionalized with catalyst, and the pore sizes tuned to offer exclusive entry to molecules participating in the catalytic process.

Plasmonic Color Thin Films

Silica coated plasmonic particles can be integrated into a much wider variety of matrices than unshelled particles. Silica coated silver and gold nanoparticles have been used to produce robust glazes and paints that can be applied to a wide variety of surfaces.

ActiBlu Color Changing Silver Nanoplates

Silica coated silver nanoplates will change color in the presence of a liquid or high humidity. This is due to the transport of water and salts across the silica shell where the high curvature silver nanoplate edges will be selectively dissolved. When the silver plates dissolve, the plasmon resonant wavelength shifts resulting in a distinct color change. By adjusting the thickness of porosity of the silica shell, the rate of color change can be adjusted. This material is being investigated as a color indicator to signify when a wound dressing should be exchanged.

Surface Enhanced Spectroscopy

Silica shells are useful for embedding dyes or other specialized molecules near to the surfaces of metal nanoparticles. These nanomaterial architectures can be designed to enhance the spectroscopic signatures of plasmonic metal nanoparticles and increase the sensitivity of spectroscopic measurements such as fluorescence and Raman. For more information on this phenomenon, check out our course on Surface Enhanced Spectroscopy.

DNA Extraction

Functionalized silica can be used to bind DNA molecules as an effective method for DNA separation. By adjusting the ionic strength of the environment through manipulation of the pH and salt concentration, DNA fragments of various sizes can be selectively separated. This approach is especially valuable for binding DNA on microchips, where extracting DNA by other methods has proven challenging.

Magnetic Separation

Silica shelled superparamagnetic nanoparticles combine the interesting properties of the core material with the enhanced stability offered by the shell material. Silica shells offer the additional benefits associated with their functionalized surfaces that facilitates binding to proteins or DNA molecules with an array of biomedical applications. Silica is a common component of columns used for biomolecular separation, thus magnetic silica particles have applications for separation in solution and microfluidic devices.

Additionally, a silica coating on magnetite particles can serve as an interface or spacer for attachment of a different material with interesting optical properties, such as a plasmonic metal or a fluorescent quantum dot that can couple to the magnetic nanoparticle core. For more information about interfacing silica with magnetic materials, visit this page about our Custom Magnetic Nanomaterials.

Instrumental Method Development

Silica nanoparticles are commonly used as standards for instrumental method development, including single-particle ICP-MS (SP-ICP-MS). Silica presents unique challenges for ICP-MS characterization due to high background at the m/z value of silicon's most abundant isotope (28Si).

Check out this Application Note to see how Perkin Elmer uses nanoComposix silica nanoparticles to overcome these challenges and analytically quantify Si content by SP-ICP-MS.

Contact us to discuss your requirements of silicon dioxide nanoparticles. Our experienced sales team can help you identify the options that best suit your needs.

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