EAN: | 9781402034732 |
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Sachgruppe: | Physik, Astronomie |
Sprache: | Englisch |
Seitenzahl: | 256 |
Produktart: | Gebunden |
Herausgeber: | Nickel, Norbert H. Terukov, Evgenii |
Veröffentlichungsdatum: | 18.08.2005 |
Untertitel: | Proceedings of the NATO Advanced Research Workshop on Zinc Oxide as a Material for Micro- and Optoelectronic Applications, held in St. Petersburg, Russia, from 23 to 25 June 2004 |
Schlagworte: | Elektronik / Mikroelektronik Elektronik / Optoelektronik Mikroelektronik Optoelektronik |
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Recently, a significant effort has been devoted to the investigation of ZnO as a suitable semiconductor for UV light-emitting diodes, lasers, and detectors and hetero-substrates for GaN. Research is driven not only by the technological requirements of state-of-the-art applications but also by the lack of a fundamental understanding of growth processes, the role of intrinsic defects and dopants, and the properties of hydrogen. The NATO Advanced Research Workshop on ¿Zinc oxide as a material for micro- and optoelectronic applications¿, held from June 23 to June 25 2004 in St. Petersburg, Russia, was organized accordingly and started with the growth of ZnO. A variety of growth methods for bulk and layer growth were discussed. These techniques comprised growth methods such as closed space vapor transport (CSVT), metal-organic chemical vapor deposition, reactive ion sputtering, and pulsed laser deposition. From a structural point of view using these growth techniques ZnO can be fabricated ranging from single crystalline bulk material to polycrystalline ZnO and nanowhiskers. A major aspect of the ZnO growth is doping. n-type doping is relatively easy to accomplish with elements such al Al or Ga. At room temperature single crystal ZnO exhibits a resistivity of about 0. 3 -cm, an electron mobility of 2 17 -3 225 cm /Vs, and a carrier concentration of 10 cm . In n-type ZnO two shallow donors are observable with activation energies of 30 ¿ 40 meV and 60 ¿ 70 meV.