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Glass microspheres are microscopic spheres of glass manufactured for a wide variety of uses in research, medicine, consumer goods and various industries. Glass microspheres are usually between 1 to 1000 micrometers in diameter, although the sizes can range from 100 nanometers to 5 millimeters in diameter. Hollow glass microspheres, sometimes termed microballoons, or glass bubbles have diameters ranging from 10 to 300 micrometers.

Hollow spheres are used as a lightweight filler in composite materials such as syntactic foam and lightweight concrete.^[1] Microballoons give syntactic foam its light weight, low thermal conductivity, and a resistance to compressive stress that far exceeds that of other foams. These properties are exploited in the hulls of submersibles and deep-sea oil drilling equipment, where other types of foam would implode. Hollow spheres of other materials create syntactic foams with different properties, for example ceramic balloons can make a light syntactic aluminium foam.^[2]

Hollow spheres also have uses ranging from storage and slow release of pharmaceuticals and radioactive tracers to research in controlled storage and release of hydrogen.^[3] Microspheres are also used in composites to fill polymer resins for specific characteristics such as weight, sandability and sealing surfaces. When making surfboards for example, shapers seal the EPS foam blanks with epoxy and microballoons to create an impermeable and easily sanded surface upon which fiberglass laminates are applied.

Glass microspheres can be made by heating tiny droplets of dissolved water glass in a process known as ultrasonic spray pyrolysis (USP), and properties can be improved somewhat by using a chemical treatment to remove some of the sodium.^[4] Sodium depletion has also allowed hollow glass microspheres to be used in chemically sensitive resin systems, such as long pot life epoxies or non-blown polyurethane composites

Additional functionalities, such as silane coatings, are commonly added to the surface of hollow glass microspheres to increase the matrix/microspheres interfacial strength (the common failure point when stressed in a tensile manner).

Microspheres made of high quality optical glass, can be produced for research on the field of optical resonators or cavities.^[5]

Glass microspheres are also produced as waste product in coal-fired power stations. In this case the product would be generally termed "cenosphere" and carry an aluminosilicate chemistry (as opposed to the sodium silica chemistry of engineered spheres). Small amounts of silica in the coal are melted and as they rise up the chimneystack, expand and form small hollow spheres. These spheres are collected together with the ash, which is pumped in a water mixture to the resident ash dam. Some of the particles do not become hollow and sink in the ash dams, while the hollow ones float on the surface of the dams. They become a nuisance, especially when they dry, as they become airborne and blow over into surrounding areas.

Application

Microspheres have been used to produce focal regions, known as photonic nanojets and whose sizes are below the micrometric scale. Previous research has demonstrated experimentally and with simulations the use of microspheres in order to increase the signal intensity obtained in different experiments. A confirmation of the photonic jet in the microwave scale, observing the backscattering enhancement that occurred when metallic particles where introduced in the focus area. A measurable enhancement of the backscattered light in the visible range was obtained when a gold nanoparticle was placed inside the photonic nanojet region produced by a dielectric microsphere with a 4.4 μm diameter. A use of nanojets produced by transparent microspheres in order to excite optical active materials, under upconversion processes with different numbers of excitation photons, has been analyzed as well.^[6]

Dispensing of microspheres

Dispensing of microspheres can be a difficult task. When utilizing microspheres as a filler for standard mixing and dispensing machines, a breakage rate of up to 80% can occur, depending upon factors such as pump choice, material viscosity, material agitation, and temperature. Customized dispensers for microsphere-filled materials may reduce the microsphere breakage rate to a minimal amount. A progressive cavity pump is the pump of choice for dispensing materials with microspheres, which can reduce microsphere breakage as much as 80%.

References

^ "Whatever Floats Your Boat, Clemson Student Chapter of the American Society of Civil Engineers". ces.clemson.edu
^ Ray Erikson (1 January 1999). Foams on the Cutting Edge. Mechanical Engineering-CIME
^ J.E. Shelby, M.M. Hall, and F.C. Raszewski (2007). A radically new method for hydrogen storage in hollow glass microspheres. DOE Technical Report FG26-04NT42170.
^ Isobe, Hiroshi; Tokunaga, Ichiro; Nagai, Noriyoshi; Kaneko, Katsumi (2011). "Characterization of hydrated silicate glass microballoons". Journal of Materials Research. 11 (11): 2908. Bibcode:1996JMatR..11.2908I. doi:10.1557/JMR.1996.0368.
^ "Optical Resonators".
^ Pérez-Rodríguez, C.; Imanieh, M.H.; Martín, L.L; Ríos, S.; Martín, I.R.; Yekta, Bijan Eftekhari (November 2013). "Study of the focusing effect of silica microspheres on the upconversion of Er3+–Yb3+ codoped glass ceramics". Journal of Alloys and Compounds. 576: 363–368. doi:10.1016/j.jallcom.2013.05.222.

External links

Glass vs Polyethylene Microspheres

[1] "Whatever Floats Your Boat, Clemson Student Chapter of the American Society of Civil Engineers". ces.clemson.edu

[2] Ray Erikson (1 January 1999). Foams on the Cutting Edge. Mechanical Engineering-CIME

[3] J.E. Shelby, M.M. Hall, and F.C. Raszewski (2007). A radically new method for hydrogen storage in hollow glass microspheres. DOE Technical Report FG26-04NT42170.

[4] Isobe, Hiroshi; Tokunaga, Ichiro; Nagai, Noriyoshi; Kaneko, Katsumi (2011). "Characterization of hydrated silicate glass microballoons". Journal of Materials Research. 11 (11): 2908. Bibcode:1996JMatR..11.2908I. doi:10.1557/JMR.1996.0368.

[5] "Optical Resonators".

[6] Pérez-Rodríguez, C.; Imanieh, M.H.; Martín, L.L; Ríos, S.; Martín, I.R.; Yekta, Bijan Eftekhari (November 2013). "Study of the focusing effect of silica microspheres on the upconversion of Er3+–Yb3+ codoped glass ceramics". Journal of Alloys and Compounds. 576: 363–368. doi:10.1016/j.jallcom.2013.05.222.

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@@ Line 3: / Line 3: @@
 '''Glass microspheres''' are [[microscopic]] spheres of [[glass]] manufactured for a wide variety of uses in [[research]], [[medicine]], [[consumer goods]] and various industries. Glass microspheres are usually between 1 to 1000 micrometers in diameter, although the sizes can range from 100 nanometers to 5 millimeters in diameter. Hollow glass microspheres, sometimes termed '''microballoons''', or '''glass bubbles''' have diameters ranging from 10 to 300 [[micrometre|micrometer]]s.
-Hollow spheres are used as a lightweight [[aggregate (composite)|filler]] in [[composite material]]s such as [[syntactic foam]] and [[lightweight concrete]].<ref>[http://www.ces.clemson.edu/earnest/0699pages/16.htm "Whatever Floats Your Boat, Clemson Student Chapter of the American Society of Civil Engineers"]. ces.clemson.edu</ref> Microballoons give syntactic foam its light weight, low [[thermal conductivity]], and a resistance to [[compressive stress]] that far exceeds that of other foams.<ref>Common Microballoons have a density of 0.15 to 0.20 g/cm<sup>3</sup>, with an isostatic crush strength of 300 to 500 psi. Denser, high strength forms offer 0.38 g/cm<sup>3</sup> with 5500 psi strength, and 0.6 g/cm<sup>3</sup> (still offering considerable flotation) with 18,000 psi crush pressure.</ref>  These properties are exploited in the hulls of [[submersible]]s and deep-sea oil drilling equipment, where other types of foam would [[Implosion (mechanical process)|implode]].  Hollow spheres of other materials create syntactic foams with different properties, for example ceramic balloons can make a light syntactic [[aluminium]] foam.<ref>Ray Erikson  (1 January 1999). [http://web.archive.org/web/20050604075250/http://www.memagazine.org/backissues/january99/features/foams/foams.html Foams on the Cutting Edge]. Mechanical Engineering-CIME</ref>
+Hollow spheres are used as a lightweight [[aggregate (composite)|filler]] in [[composite material]]s such as [[syntactic foam]] and [[lightweight concrete]].<ref>[http://www.ces.clemson.edu/earnest/0699pages/16.htm "Whatever Floats Your Boat, Clemson Student Chapter of the American Society of Civil Engineers"]. ces.clemson.edu</ref> Microballoons give syntactic foam its light weight, low [[thermal conductivity]], and a resistance to [[compressive stress]] that far exceeds that of other foams. These properties are exploited in the hulls of [[submersible]]s and deep-sea oil drilling equipment, where other types of foam would [[Implosion (mechanical process)|implode]].  Hollow spheres of other materials create syntactic foams with different properties, for example ceramic balloons can make a light syntactic [[aluminium]] foam.<ref>Ray Erikson  (1 January 1999). [http://web.archive.org/web/20050604075250/http://www.memagazine.org/backissues/january99/features/foams/foams.html Foams on the Cutting Edge]. Mechanical Engineering-CIME</ref>
 Hollow spheres also have uses ranging from storage and slow release of [[pharmaceutical]]s and [[radioactive tracer]]s to research in controlled [[hydrogen storage|storage]] and release of [[hydrogen]].<ref>J.E. Shelby, M.M. Hall, and F.C. Raszewski (2007). [http://www.osti.gov/bridge/product.biblio.jsp?query_id=0&page=0&osti_id=918691 A radically new method for hydrogen storage in hollow glass microspheres].  DOE Technical Report FG26-04NT42170.</ref> Microspheres are also used in composites to fill polymer resins for specific characteristics such as weight, sandability and sealing surfaces. When making surfboards for example, shapers seal the [[Polystyrene#Expanded polystyrene|EPS]] foam blanks with epoxy and microballoons to create an impermeable and easily sanded surface upon which fiberglass laminates are applied.

v t e Glass science topics
Basics	Glass Glass transition Supercooling
Formulation	AgInSbTe Bioglass Borophosphosilicate glass Borosilicate glass Ceramic glaze Chalcogenide glass Cobalt glass Cranberry glass Crown glass Flint glass Fluorosilicate glass Fused quartz GeSbTe Gold ruby glass Lead glass Milk glass Phosphosilicate glass Photochromic lens glass Silicate glass Soda–lime glass Sodium hexametaphosphate Soluble glass Tellurite glass Thoriated glass Ultra low expansion glass Uranium glass Vitreous enamel Wood's glass ZBLAN
Glass-ceramics	Bioactive glass CorningWare Glass-ceramic-to-metal seals Macor Zerodur
Preparation	Annealing Chemical vapor deposition Glass batch calculation Glass forming Glass melting Glass modeling Ion implantation Liquidus temperature sol–gel technique Viscosity Vitrification
Optics	Achromat Dispersion Gradient-index optics Hydrogen darkening Optical amplifier Optical fiber Optical lens design Photochromic lens Photosensitive glass Refraction Transparent materials
Surface modification	Anti-reflective coating Chemically strengthened glass Corrosion Dealkalization DNA microarray Hydrogen darkening Insulated glazing Porous glass Self-cleaning glass sol–gel technique Tempered glass
Diverse topics	Conservation and restoration of glass objects Glass-coated wire Safety glass Glass databases Glass electrode Glass fiber reinforced concrete Glass ionomer cement Glass microspheres Glass-reinforced plastic Glass cloth Glass-to-metal seal Porous glass Pre-preg Prince Rupert's drops Radioactive waste vitrification Windshield Glass fiber

Revision as of 17:24, 31 March 2015

Application

Dispensing of microspheres

See also

References

External links