Quartz glass
General | |
---|---|
Surname | Quartz glass |
other names | fused silica , fused silica |
Molecular formula | SiO 2 |
Brief description | Pure SiO 2 glass |
properties | |
Physical Properties | |
density | 2.201 g / cm³ |
Tensile strength (strongly dependent on shape and surface quality) |
approx. 50 N / mm² |
hardness | 5.3-6.5 Mohs; 8.8 GPa |
Speed of sound , longitudinal | 5930 m / s |
Speed of sound , transversal | 3750 m / s |
Impurities | typ. 10-1000 ppm |
Optical properties | |
transmission | 170-5000 nm |
Refractive index | 1.46 at 589.3 nm |
Brewster angle | 55.58 ° |
Thermal properties | |
Thermal expansion coefficient 0… 600 ° C | 0.54 10 −6 K −1 |
Specific heat capacity 0… 900 ° C | 1052 J / (kg K) |
Thermal conductivity (20 ° C ) | 1.38 W / (m K) |
Phonon thermal conductivity (2000 ° C) | 15 W / (m K) |
Transformation point | 1130 ° C |
Littleton temperature | 1760 ° C |
Processing temperature | > 2000 ° C |
boiling point | 2230 ° C |
Quartz glass , also referred to as silica glass , is a glass that, in contrast to conventional glasses, does not contain any additions of sodium carbonate or calcium oxide . H. consists of pure silicon dioxide (SiO 2 ). Industrially produced quartz glass has different concentrations of impurities, depending on the raw material and production process, which are in the ppm or, for synthetic silica glass, in the ppb range.
It can be obtained by melting and resolidifying quartz (quartz sand or artificially produced), hence the name quartz glass and the English name fused quartz or fused silica .
Naturally occurring quartz glass is called lechatelierite .
Richard Küch (1860–1915), physicist and chemist, discovered in 1899 that silicon dioxide can be melted in an oxyhydrogen flame without bubbles and in the highest purity, and made quartz glass usable as a mass product for industry.
properties
- Permeability for infrared to ultraviolet radiation (from 170 nm to 5 µm wavelength)
- Low thermal expansion coefficient and high resistance to temperature changes
- High chemical resistance: With the exception of hydrofluoric acid and hot phosphoric acid , quartz glass is not attacked by any acid and is neutral to many other substances.
- The dielectric strength is approx. 40 kV / mm, which makes quartz glass a good insulation material in electrical engineering components such as optocouplers .
- The softening temperature is significantly higher than that of other glasses.
Applications
- Window and lens material for ultraviolet optics ( excimer laser , photolithography )
- Insulation layer in semiconductor components ( MOS technology )
- Bulbs for halogen lamps
- Bulbs for xenon gas discharge lamps ( xenon light , photo flash, stroboscope)
- Discharge vessels for mercury vapor lamps (high and ultra high pressure lamps, also low pressure lamps if UV emission is desired)
- Material for equipment in semiconductor manufacturing
- Cuvettes for instrumental analysis
- Material for fiber optic cables (laser beam transmission, communications technology)
- Windows and components of the heat protection tiles of the space shuttle
- Retroreflectors for measuring lasers on the EDM lander from ExoMars
- Viewing and measuring windows in hot environments ( ovens , engines , gas turbines )
- Insulation material in electrotechnical components such as optocouplers
- Musical instruments ( verrophone , glass harmonica , glass harp )
- Protective tube for water disinfection with UV radiation
- Substrate for Raman spectroscopy measurements
High-purity quartz glass is transparent in the wavelength range from 190 nm to 3.5 µm, but normally has an absorption band of around 2.5 to 3 µm caused by OH - groups. Improved infrared transmission at wavelengths of 2.2 to 3 µm is achieved through a reduced hydroxyl group ( OH group ) content. The normal value is 100 ppm , with improved IR transmission below 1 to 3 ppm.
By doping with titanium , UV-C absorption can be achieved; by doping with cerium , absorption in the entire ultraviolet range can be achieved (UV-blocking halogen lamps ).
In instrumental analysis , quartz glass cuvettes are used to measure volumes below 50 nl . It is only the special properties of quartz glass that enable measuring equipment and supply channels with a diameter of less than 100 µm.
Because of the sometimes very low specific absorption of the samples, the layer thickness cannot be reduced at will. It follows from this that ever smaller cross-sections of the measuring equipment and the supply channels down to a diameter of less than 100 µm are required. In this way, measuring volumes of less than 50 nl are achieved. The production takes place by means of microlithography and etching . Further important properties of quartz glass for the production of cuvettes are its high degree of transmission between approx. 200 nm and 4 µm, its good chemical resistance and its low electrical conductivity .
The disadvantage is that quartz glass is difficult to process.
The very low expansion coefficient of quartz glass makes it highly resistant to temperature changes. This and the high softening temperature of the quartz glass allow components, tubes and vessels to be manufactured that can withstand temperatures of up to max. Withstand 1400 ° C.
Individual evidence
- ↑ Thomas Jüstel, Sebastian Schwung: Phosphors, light sources, lasers, luminescence . Springer-Verlag, Berlin, Heidelberg 2016, ISBN 978-3-662-48455-5 , pp. 207 ( limited preview in Google Book search).
- ↑ Product information page of the manufacturer Heraeus Conamic , www.heraeus-conamic.de
- ↑ H. Scholze: Glass. Nature, structure and properties . 1988, ISBN 3-540-18977-7 , pp. 154 .
- ↑ Chemical purity of quartz glass , www.heraeus-conamic.de
- ^ Richard Küch and Heraeus: Creating Innovations , press release from Heraeus Holding GmbH
- ↑ Product information page of the crystal dealer Korth Kristalle , www.korth.de, accessed on June 21, 2012
- ↑ H. Scholze: Glass. Nature, structure and properties . 1988, ISBN 3-540-18977-7 , pp. 213 f .