Luminescence: Difference between revisions

Luminol and hemoglobin, an example of chemoluminescence

Luminescence is light that usually occurs at low temperatures, and is thus a form of cold body radiation. It can be caused by chemical reactions, electrical energy, subatomic motions, or stress on a crystal. This distinguishes luminescence from incandescence, which is light generated by high temperatures. Historically, radioactivity was thought of as a form of "radioluminescence", although it is today considered to be separate since it involves more than electromagnetic radiation.

The dials, hands, scales and signs of aviation and navigational instruments and markings are often coated with luminescent materials, in a process known as luminising.

The following are types of luminescence

• Bioluminescence, by a living organism
• Chemoluminescence, resulting of a chemical reaction
  • Electrochemiluminescence, by an electrochemical reaction
• Crystalloluminescence, produced during crystallization
• Electroluminescence, in response to an electric current passed through it
  • Cathodoluminescence, where beam of electrons impacts on a luminescent material such as a phosphor
• Mechanoluminescence, resulting from any mechanical action on a solid
  • Triboluminescence, generated when bonds in a material are broken when that material is scratched, crushed, or rubbed
  • Fractoluminescence, generated when bonds in certain crystals are broken by fractures
  • Piezoluminescence, produced by the action of pressure on certain solids^[1]
• Photoluminescence, absorption of photons causing re-radiation of photons
  • Phosphorescence, delayed re-radiation
  • Fluorescence, where the emitted photons are of lower energy than those absorbed
• Radioluminescence, produced in a material by the bombardment of ionizing radiation
• Sonoluminescence, from imploding bubbles in a liquid when excited by sound
• Thermoluminescence, when absorbed light is re-emitted on heating.

Applications

• Phosphors, emitting light when irradiated by higher-energy electromagnetic radiation or particle radiation
• Phosphor thermometry, phosphorescence can be used to detect the temperature of an object eg a gas turbine component ^[2],^[3],^[4],^[5]
• Thermoluminescence dating

References

1. http://adsabs.harvard.edu/abs/1982PhLA...90...93A
2. X. Chen, Z. Mutasim, J. Price, J. P. Feist, A. L. Heyes and S. Seefeldt (2005), 'Industrial sensor TBCs: Studies on temperature detection and durability', International Journal of Applied Ceramic Technology, Vol. 2, No. 5, pp. 414-421.
3. A. L. Heyes, S. Seefeldt, J. P Feist (2005), ‘Two-colour thermometry for surface temperature measurement’, Optics and Laser Technology, 38, pp.257-265.
4. R.J.L.Steenbakker,J.P.Feist,R.G.Wellmann,J.R.Nicholls, (2008),SENSOR TBCs: REMOTE IN-SITU CONDITION MONITORING OF EB-PVD COATINGS AT ELEVATED TEMPERATURES, GT2008-51192,Proceedings of ASME Turbo Expo 2008: Power for Land, Sea and Air,June 9-13, 2008, Berlin, Germany.
5. J. P. Feist, A. L. Heyes and J. R. Nicholls (2001), 'Phosphor thermometry in an electron beam physical vapour deposition produced thermal barrier coating doped with dysprosium', Proceedings of Institution of Mechanical Engineers, Vol. 215 Part G, pp. 333-340.

External links

• Luminescence chart
• Luminescence on Scienceworld
• Fluorophores.org The database of luminescent dyes
• Luminiscent microspheres
• Aurea Technology Ultra low noise and High QE Single Photon Detector.